WO2001084581A2 - Predetermined symmetrically balanced amalgam with complementary paired portions comprising shielding electrodes and shielded electrodes and other predetermined element portions for symmetrically balanced and complementary energy portion conditioning - Google Patents
Predetermined symmetrically balanced amalgam with complementary paired portions comprising shielding electrodes and shielded electrodes and other predetermined element portions for symmetrically balanced and complementary energy portion conditioning Download PDFInfo
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- WO2001084581A2 WO2001084581A2 PCT/US2001/013911 US0113911W WO0184581A2 WO 2001084581 A2 WO2001084581 A2 WO 2001084581A2 US 0113911 W US0113911 W US 0113911W WO 0184581 A2 WO0184581 A2 WO 0184581A2
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K9/00—Screening of apparatus or components against electric or magnetic fields
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L23/00—Details of semiconductor or other solid state devices
- H01L23/552—Protection against radiation, e.g. light or electromagnetic waves
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L23/00—Details of semiconductor or other solid state devices
- H01L23/48—Arrangements for conducting electric current to or from the solid state body in operation, e.g. leads, terminal arrangements ; Selection of materials therefor
- H01L23/50—Arrangements for conducting electric current to or from the solid state body in operation, e.g. leads, terminal arrangements ; Selection of materials therefor for integrated circuit devices, e.g. power bus, number of leads
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L2223/00—Details relating to semiconductor or other solid state devices covered by the group H01L23/00
- H01L2223/58—Structural electrical arrangements for semiconductor devices not otherwise provided for
- H01L2223/64—Impedance arrangements
- H01L2223/66—High-frequency adaptations
- H01L2223/6605—High-frequency electrical connections
- H01L2223/6616—Vertical connections, e.g. vias
- H01L2223/6622—Coaxial feed-throughs in active or passive substrates
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L2924/00—Indexing scheme for arrangements or methods for connecting or disconnecting semiconductor or solid-state bodies as covered by H01L24/00
- H01L2924/0001—Technical content checked by a classifier
- H01L2924/0002—Not covered by any one of groups H01L24/00, H01L24/00 and H01L2224/00
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L2924/00—Indexing scheme for arrangements or methods for connecting or disconnecting semiconductor or solid-state bodies as covered by H01L24/00
- H01L2924/30—Technical effects
- H01L2924/301—Electrical effects
- H01L2924/3011—Impedance
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K1/00—Printed circuits
- H05K1/02—Details
- H05K1/14—Structural association of two or more printed circuits
- H05K1/141—One or more single auxiliary printed circuits mounted on a main printed circuit, e.g. modules, adapters
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K1/00—Printed circuits
- H05K1/16—Printed circuits incorporating printed electric components, e.g. printed resistor, capacitor, inductor
- H05K1/162—Printed circuits incorporating printed electric components, e.g. printed resistor, capacitor, inductor incorporating printed capacitors
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K3/00—Apparatus or processes for manufacturing printed circuits
- H05K3/30—Assembling printed circuits with electric components, e.g. with resistor
- H05K3/32—Assembling printed circuits with electric components, e.g. with resistor electrically connecting electric components or wires to printed circuits
- H05K3/34—Assembling printed circuits with electric components, e.g. with resistor electrically connecting electric components or wires to printed circuits by soldering
- H05K3/341—Surface mounted components
- H05K3/3431—Leadless components
- H05K3/3436—Leadless components having an array of bottom contacts, e.g. pad grid array or ball grid array components
Definitions
- the invention relates to a predetermined balanced total electrode structure also uses a grouping of identically configured, and balanced positioned, shielding electrodes that are amalgamated in sequential combination with predetermined, complimentary balanced shielded electrodes groupings and other predetermined elements that are together, practicable to provide predetermined multiple energy conditioning functions operable upon portions of propagating energy as well simultaneously being operable to provide a common, voltage reference function operable for at least dynamic circuit operations
- a novel and unique approach is to provide an invention that allows for predetermined and closely positioned parallel energy pathways or electrodes to operate dynamically in close proximity to one another to allow development of a low impedance energy pathway that will develop upon a third parallel energy pathway not normally considered as integral for energized circuit operations.
- This third energy pathway is normally found to be electrically isolated from, but be found internally adjacent to, the electrically opposing differential electrode energy pathways or power/signal planes.
- This third energy pathway can also be utilized in one invention circuit assembly for multiple attachments as opposed to utilizing many. individual discrete low impedance decoupling capacitors, positioned in parallel within a prior art circuit assembly in an attempt to accomplish the same goal.
- the present invention discloses a new predetermined embodiment that can be part of a predetermined circuit system to provide predetermined circuit protection and predetermined energy conditioning from various invention embodiments, invention assemblies, invention assembly circuit arrangements that will help also provide the current passive component manufacturing infrastructure with multifunctional energy conditioning structure that also allows an unprecedented ease of adaptability or production changeover as compared to the prior art.
- the invention includes predetermined combinations of at least three, electrode groupings or grouped pluralities of electrodes.
- the three groupings include at least two groupings of complimentary oriented and positioned, shielded electrodes that are selectively or predetermined and interleaved between a third grouping of electrodes, which will operate as shielding electrodes, relative to the at least two groupings of complimentary oriented and positioned, shielded electrodes.
- the three electrode groupings are arranged in a predetermined manner to be practicable for energized operations that will be practicable or operable to allow the creation of at least a dynamic energy pathway of low impedance or low impedance condition that can be operable along a portion of predetermined internal invention energy pathway portions and/or can be operable for a portion of predetermined, conductively coupled, common external conductive portion or pathway.
- An external portion of a predetermined, conductively coupled, common conductive portion or pathway in conductively coupled combination with a predetermined physically balanced, amalgamated shielding, common electrode structure can be part of an electrically coupled portion of a predetermined circuit portion to complete a predetermined energy conditioning circuit network or predetermined energy distribution network, or circuit that aids active electronic componentry by creating balanced, electromagnetic actuated impedance states at energization with amalgamated, grouped pluralities of at least two complementary oriented but commonly comprised groups of same-sized shielded , complementary oriented, electrodes that are also arraigned in-part, by at least a predetermined manner to be practicable for energized complementary or differential electrical operations that allows for sustained, smooth energy portion conditioning as well as sustained, simultaneous electromagnetic emissions suppression of stray energy portions or parasitics that would normally be operable to disrupt predetermined energized circuit portions with electrical or dynamic discontinuities.
- predetermined energy conditioning embodiments comprising various electrodes each comprising an electrode, main-body portion with or without, predetermined electrode lead portions that are grouped and placed into relative to each other, both individually and as a part of a predetermined plurality of homogenous (not necessarily, in terms of material-types, composition), physically-configured, electrode groupings or a predetermined plurality of homogenous (not in not necessarily, terms of material-types, composition), physically-configured energy pathways, predetermined for combined, interposing positioning arrangements that includes other, predetermined conductive and non-conductive element portions that art also predetermined in advance to form a predetermined assembly or assemblies and variations.
- the layered, multi-functional, predetermined common electrode shield structure also provides electrical shielding to portions of propagating energy that will gather or be found near portions of electrode with predetermined, main-body portions' edges or edgings.
- FIG. 1A shows a top view of a portion of a cage-like electrode shield structure portion with a by-pass electrode of the present invention
- FIG. 1 B shows an exploded perspective view of a portion of the present invention comprising predetermined, balanced groupings of internally positioned shielding common electrodes;
- FIG. 2A shows an exploded perspective view depicting a predetermined multi- electrode stacking sequence with two differential, bypass propagational groupings, in combination with a portion of the universal shielding, common electrode architecture of FIG. 1 B in a double bypass electrode configuration using two sandwiching outer "-IM" electrode shields in accordance with the present invention
- FIG. 2B shows cross-sectional view of the embodiment of the present invention of FIG. 2B taken along a longitudinal centerline between external electrode material connection portions;
- FIG. 2C shows cross-sectional view of the embodiment of the present invention of FIG. 2B taken along a longitudinal centerline between external common electrode material connection portions and rotated 90 degrees with respect to FIG. 2B;
- FIG. 3 A shows a detailed plan view of a portion of a shielding electrode pathway portion depicting a typical spilt electrode configuration in accordance with the present invention
- FIG. 3B shows a detailed plan view cross-section of FIG. 3 A depicting a typical spilt electrode configuration in accordance with the present invention
- FIG. 3C shows the a practicable balanced shielded electrode alignments viewed in accordance with the present invention
- FIG. 4 is a cross-section view of another embodiment of the present invention having a predetermined multi-electrode stacking sequence 399 with (2) differential, shielded propagational groupings, in combination with (1) common shielding electrode propagational grouping which comprises a portion of shielding electrode architecture 4000 of FIG. IB, but without the sandwiching outer "-IM" electrode shields with single shielded electrodes depicting the versatility of the shielding structure with various set back zones and distances in accordance with the principles of the invention;
- FIG. 5A is showing a exploded perspective view depicting an upper portion of alternative arrangement embodiment of FIG. 2A showing one sandwiching outer "NON- IM" electrode shield with internally coupled conductive structures disposed through operable as join with a smaller sized, electrode shield in accordance with the principles of the invention;
- FIG. 5B is a cross-section view of multi-electrode predetermined stacking sequence of a shielding electrode architecture with differential shielded electrodes depicting FIG. 5A showing two sandwiching outer "-IM" electrode shields with internally coupled conductive structures disposed through operable as join with a smaller sized, electrode shield in accordance with the principles of the invention;
- FIG. 5C is showing an exploded perspective view depicting two variations of portions of a differential shielded electrode arrangement that can be made from FIG. 2 A in accordance with the principles of the invention
- FIG. 5D is showing cross-section view of multi-electrode predetermined stacking sequence of a shielding electrode architecture with differential shielded electrodes depicting one variation of the two variation portions of FIG. 6A utilized within a portion the shielding electrode structure of FIG. 2 A using the single central shielding electrode with sandwiching outer "-IM" electrode shields in accordance with the principles of the invention;
- FIG. 6A is showing a cross-sectional view taken along a longitudinal bisector between complimentary external electrodes depicting two variations of portions of a differential shielded electrode arrangement that can be made from FIG. 2A in accordance with the principles of the invention
- FIG. 6B shows the FIG. 6A view rotated to 90 degrees and viewed in accordance with the present invention
- FIG. 7A is showing an a cross-sectional view taken along a longitudinal bisector between complimentary external electrodes depicting a variation of the 3 -energy pathway electrode arrangement of FIGS. 2A,2B and 2C, in accordance with the principles of the invention
- FIG. 7B shows the FIG. 7 A view rotated to 90 degrees and viewed in accordance with the present invention
- FIG. 8 A is showing a cross-sectional view taken along a longitudinal bisector between complimentary external electrodes depicting a variation of the 3 -energy pathway electrode arrangement of FIGS. 2A,2B and 2C, in accordance with the principles of the invention
- FIG. 8B shows the FIG. 8A view rotated to 90 degrees and viewed in accordance with the present invention
- FIG. 9A is showing a cross-sectional view taken along a longitudinal bisector between complimentary external electrodes depicting a variation of the 3-energy pathway electrode arrangement of FIGS. 2A,2B and 2C, in accordance with the principles of the invention
- FIG. 9B shows the FIG. 9A view rotated to 90 degrees and viewed in accordance with the present invention
- FIG. 10A is showing an exploded perspective view depicting a variation of the 3-energy pathway electrode arrangement of FIGS. 2A,2B and 2C, in accordance with the principles of the invention;
- FIG. 1 OB shows the FIG. 1 OA view rotated to 90 degrees and viewed in accordance with the present invention;
- FIG. 11A is showing a cross-sectional view taken along a longitudinal bisector between complimentary external electrodes depicting a variation of the 3-energy pathway electrode arrangement of FIGS. 2A,2B and 2C, in accordance with the principles of the invention
- FIG. 1 IB shows the FIG. 11 A ⁇ iew rotated to 90 degrees and viewed in accordance with the present invention
- FIG. 12A is showing a cross-sectional view taken along a longitudinal bisector between complimentary external electrodes depicting a variation of the 3-energy pathway electrode arrangement of FIGS. 2A,2B and 2C, in accordance with the principles of the invention
- FIG. 12B shows the FIG. 12A view rotated to 90 degrees and viewed in accordance with the present invention
- FIG. 13 A is showing a cross-sectional view taken along a longitudinal bisector between complimentary external electrodes depicting a variation of the 3-energy pathway electrode arrangement of FIGS. 2A,2B and 2C, in accordance with the principles of the invention;
- FIG. 13B shows the FIG. 13A view rotated to 90 degrees and viewed in accordance with the present invention
- FIG. 14A shows a circuit assembly or circuit arrangement practicable for maintaining simultaneous, electrical isolation of the 3 energy pathways and certain, energy portion confluences and interaction operable by dynamic operation as well as by a predetermined 'distanced' positioning, all of which are operable and relative to each other made practicable by utilizing an invention embodiment comprising a predetermined 3- energy pathway conductor arrangement as described herein, in accordance with the principles of the invention; and
- FIG. 14B is a closer view of invention circuit assembly or circuit arrangement of FIG. 14A in accordance with the principles of the invention.
- the word predetermined is to mean among others, “to determine, decide, or establish in advance” “influence or sway toward an action” “predisposed” “to determine or decide something in advance” or any evidence "that would point out through common sense or forensic investigation or records to a fact or substantial assurance to a reasonable person that an action or an assembly of the invention elements had required a human thought process before an invention structure or action had took place or even will take place "
- a predetermined, universal shielding electrode architectures' "interrelational- matrix" arrangement that comprises at least a predetermined stacked, parallel and aligned, grouping of conductively coupled, shielding electrodes comprising at least a main-body portion 81, each is disclosed.
- This is a common, shielding electrode structure formed as an inter-relational-matrix static structure that becomes a full and symmetrical, hierarchy progression in dynamic operations as part of a predetermined element combination.
- the universal shielding electrode (conductor) architectures' stacked, parallel and aligned, groupings of conductively coupled, shielding and containment structures further comprises a balanced predetermined, grouping of homogenous, interconnected, common, shielding electrodes each with a main-body portion 81 with predetermined shaped surfaces, of which a main-body portion 81 can also comprise or include common, shielding electrode lead attachment portion(s) 79G that are operable to allow further operable attachment or conductive coupling with either, other, predetermined conductive material portion(s), that are in-turn, each (the predetermined conductive material portion(s)) are also operable for shielding electrode lead attachment portion(s) 79G as practicable, themselves, for further conductive coupling to predetermined portions for predetermined electrical circuit coupling or to predetermined intermediate conductor portions or just direct energy pathway portions for predetermined electrical circuit coupling, all for eventual, predetermined energized or dynamic, operations.
- the universal shielding electrode (conductor) architectures' stacked, parallel and aligned, groupings of conductively coupled, shielding and containment structures can be combined by at least a sequenced, predetermined manufactured operation as will be described.
- the invention can also comprise a predetermined balanced amalgamation of a stacked, parallel shielding electrode arrangement and alignment that is formed, at least in- part as a relative, 3-demensional offset/outset or inset predetermined positioning arrangement of the various predetermined shielded and/or fully shielded, complementary positioned, predetermined and same-size, portions of paired, shielded electrodes with main-body portion 80, each, that are symmetrically arranged respective to each other operable for common predetermined, complementary alignment.
- These shielded electrodes with main-body portion 80 are also operable for mutually covering, registration or stacked alignment arrangement to each other that allows for these complementary positioned, predetermined and same-size, electrode, main-body portions 80 of the paired differential electrodes to be complementary, in an electrically dynamic operational circuit, as well.
- shielded electrode main-body portion 80s are all at least practicable to be arranged by predetermined manner to operable in the range to be at least fully shielded or a fully shielded in terms of their main-body portion 80 relative to each other as well as relative to the predetermined, shielding electrodes with at least main-body portion 81 and their full range of shielding of the differentials from other external energy, not of the paired differential electrodes when energized into a circuitry by predetermined manner.
- a portion of the predetermined, universal shielding electrode architecture is operable to physically shield or provide a shielding function in order to either fully isolate and immure these predetermined paired, differential, shielded electrode main-body portions 81 as they still maintain a full symmetrical relationship to each other within a shielding coverage of the predetermined, universal shielding electrode architectures' "interrelational-matrix" arrangement comprising at least a predetermined stacked, parallel and aligned, grouping of conductively coupled, shielding electrodes comprising at least a main-body portion 81 , each.
- the predetermined shielding and/or fully shielding electrodes are conductively coupled and will be operable together as a single conductively connected structure that is practicable for an electrically common voltage potential at energization.
- AOC predetermined area or space of physical convergence or junction
- At least one predetermined manufacturing process can be utilized to create an invention will result in a sequentially positioned formation of relatively positioned (to each other) groupings of electrodes made into an amalgamated electronic structure comprising balanced groupings of predetermined energy pathways or electrodes.
- the predetermined amalgamation of selected electrodes are formed in-part, by at least a predetermined, sequential manufacturing operation that has normally occurred before actual and final placement into an application for energization.
- predetermined manufacturing sequential placement a timing of manufacturing of the invention is disclosed which will begin with the placement of a first shielding electrode created for final amalgamation as part of a first invention units' AOC.
- This axiom is good regardless of the number or kinds of other, final electrode elements utilized as part of a first invention or variant, units' AOC that are positioned or placed in-between or within, both from a positioned, or deposited standpoint, adjacent to the first shielding electrode as described above.
- the invention will also provide predetermined types of surge protection for circuitry attached between a source and an energy utilizing- load.
- the predetermined amalgamation of selected electrodes are formed in-part, by at least a predetermined, sequential manufacturing operation that has normally occurred before actual and final placement into an application for energization.
- balanced groupings of predetermined and internally positioned electrodes can also create specific predetermined, shielding electrode architectures using a stacked hierarchy progression that can be observed statically as an arrangement of predetermined elements that are found to be positioned both, complementary and/or equally in amounts on one, of two, larger, symmetrical and parallel sides comprising material, disposed or formed as the shielding electrode's, two, main-body portions 81 of a centrally positioned, shielding electrode 800/800-IM that serves as the predetermined physical, sharing point, dividing zone, fulcrum or balancing point for equally divided remaining portions of not only a plurality of the shielding electrodes comprising the predetermined shielding structure but all the other Inventions' predetermined material elements located within an invention predetermined AOC.
- the invention and/or variations of the invention will utilize the other various predetermined common shielded electrodes, each comprising 799 material, and disposed or formed with an electrode, main-body portion 81 in a predetermined placement positioning and alignment normally to be dispersed and found on either side of the centrally positioned shielding electrode 800/800-IM, all equally divided and arranged in a balanced and predetermined physical positioning whether as described in this disclosure or not, within an AOC structure.
- Such symmetrical positioning includes reflected or rotated translation as well.
- the pairing operations yield a symmetrical electrode arrangement that can be considered a balanced electrode symmetrical design, as one will find with the invention or its' variants in most complementary energy interactions that are described as dynamic events, that are in complementary balance, by symmetry, mainly of the energies propagating along the various differential electrode pairings and common, shielding electrodes are happening simultaneously, due to many reasons.
- the electrode structure called out includes the respective electrodes' whole portion, including main-body portion
- a shielding electrode can not be found in discernable position to the naked eye in a 'reverse-mirror image positioning orientation' with any mate, because as noted, the electrode structure includes each respective electrodes' placed and coupled together as a whole, including main-body portion 81 , plus any electrode lead portion(s) 79G, which form an electrode were all portions stacked, coupled and commonly aligned, share total perimeter edge alignment as they are operable to form the single shielding, electrode structure as one unit.
- inventions and/or variations of the invention or variant will also comprise predetermined conductive structures, electrode lead portions like, 79G or 812"X", electrode termination elements or other conductive material portions, like 802"X" or
- predetermined circuit portions can also include predetermined circuit portions comprising the invention and/or variations of the invention are practicable to be made operable by combination and conductive coupling to predetermined external portions.
- balanced groupings of predetermined and internally positioned, shielding electrodes each electrode being comprised with at least an electrode, main-body portion 81 used to create a predetermined, shielding, electrode architecture using a stacked, electrode, main-body portion hierarchy progression that can be observed statically as an arrangement of predetermined elements that are found to be positioned both, complementary and/or equally in amount on one of two sides of a centrally positioned common, shielding electrode that serves as the apparent physical fulcrum or balancing point for these equally divided portions of material elements.
- Predetermined, equal integer numbers of both predetermined same-size, shielded electrodes each with at least an electrode, main-body portion 80, or differential electrodes as well as equal numbers of same-size, shielding electrodes each with at least an electrode, main-body portion 81, will normally be found on either side of a centrally positioned, shielding electrode that serves as the divider or line of balanced portions of equal interspersed numbers of these two groupings of different sized electrodes divided and arranged in a predetermined, balanced physical positioning that can include mirror image positioning and or in some cases, as reverse-mirror image positioning of paired same-size, shielded electrodes each with at least an electrode, main-body portion 80 that are described as being disposed, but separated, as a pair or pairings such that their electrode, main-body portion 80 are shielded, segregated or separated, and considered to be sandwiched between and within a stacking of at least two larger, electrode, main-body portion 81 of the similarly sized shielding electrodes within the over all invention or variant structure.
- the invention and/or variations of the invention can also comprise predetermined conductive structures, electrode main-body portions, electrode lead extension electrode termination elements or conductive portions that are practicable for predetermined circuitry attachment of these various conductive portions of the invention itself to any number of various predetermined external (to the invention) energy pathways that will create what is considered an unenergized circuit assembly.
- predetermined circuit portions can also include predetermined circuit portions comprising the invention and/or variations of the invention are practicable to be made operable by combination and conductive coupling to predetermined external portions.
- the invention is also disclosed as operable for both discrete and non-discrete structural embodiment versions and circuit assemblies where at least one pair of same- sized, complementary electrodes that are reversed-mirror images of each other are selectively positioned by predetermined manner on opposite sides of a common, shielding electrode energy pathway with respect to each other.
- the central, shielding electrode along with any other of the Invention's energy pathways can also be considered in some instances to be an electrode substrate, conductive material deposit, result of a etching away of non-conductive material to reveal conductive material, the result of a doping process that makes a normally poor or non-conductive material portion conductive for energy propagations, but in any embodiment all elements or results of a process could potentially be considered to serve as a central isolating barrier that is interposed physically and in most cases, electrically (when energized) between each same-sized, complementary electrodes of the paired same-sized, complementary electrodes or any of any other of the Invention's energy pathways or electrodes that creates an invention.
- the advantage of providing same-sized, complementary electrodes for those energy pathways requiring filtering enables the new energy conditioning filter to be constructed with conventional materials that is economical for the many possible variants of the present invention that can be construed.
- An invention will also provide for closely positioned internal parallel energy pathways of the invention to operate dynamically, in close proximity to one another, to allow development of a low impedance energy pathway or blocking function that develops upon or along another common and parallel energy pathway or amalgamated common, shielding electrode structure that is not normally considered as integral for energized circuit operations or its (the circuits') completion or maintenance for electrical operability.
- This third but common energy pathway can be found both internally within the invention as well as adjacent to the electrically opposing differential electrode energy pathways or power/signal planes and can be utilized in at least one invention variation or device for certain predetermined circuitries or bus lines as opposed to utilizing many, individual discrete low impedance decoupling energy conditioners or capacitor/resistor combinations that are positioned in parallel within a comparable circuit system in an attempt to accomplish the same goal such as high frequency decoupling.
- This invention is intended to allow for an ability to minimize, suppress or filter unwanted electromagnetic emissions resulting from differential and common mode currents flowing within electronic pathways that come under an invention(s) influence both internally, with parallel complementary aligned and positioned electrodes, as well as in combination with externally coupled and positioned circuitry portions, all in accordance with the present invention.
- the invention when energized, will also allow both the fully contained or contained and oppositely paired differential energy pathway electrodes to function with respect to one another, in balance, yet in an electrically opposite, complementary manner.
- the invention can also comprise an arrangement of same-sized, complementary electrodes into a shielding or fully shielding common, shielding electrode structure combines to form a new filter assembly.
- An arrangement of various conventional materials elements, same-sized, complementary electrodes, common electrodes or shielding electrodes that are conductively connected to each other, as well as the predetermined selective positioning process, final amalgamation, attachment and circuit coupling can also be considered as at least one invention variant.
- the usage of predetermined and selective decisions as to the various non-attachment and non-coupling of certain whole elements or portions of elements, such as same-sized, complementary electrodes, as well as the common, shielding electrodes to one another or not, can also be considered as at least one invention variant.
- Portions of this third, but common energy pathway for a circuit arrangement assembly comprising the by-pass architecture invention can be found both internally within an invention, as well as portions can be found positioned almost physically, against, but adjacent with an interposing material insulator or material with predetermined properties 801 as a buffer to the electrically opposing same-size, shielded electrodes, each with at least an electrode, main-body portion 80, or differential, shielded electrode energy pathways or power/signal planes.
- Portions of this third, but common energy pathway can be utilized in conjunction with at least one invention circuit arrangement assembly variation or device for certain predetermined circuitries or bus lines that are utilizing two other non-common energy pathways or differential, shielded energy pathways (not shown).
- This three separate energy pathway energy network or energy distribution network concept used with a single, self-contained electrode arrangement is opposed to the prior art, which often is utilizing many, individual discrete low impedance decoupling energy conditioners or capacitor/resistor combinations that are positioned in parallel within a comparable circuit system in an attempt to accomplish the same goal such as high frequency decoupling provided by a predetermined circuit arrangement assembly.
- FIG. 1A , and FIG. IB portions of predetermined, cage-like shielding electrode structure 4000 in FIG. IB and are shown in detail in FIG. 1A and FIG. 2A, 2B and 2C and accordingly, discussion will move freely between FIGS. 1, 2A and 2A , 2B and 2C to disclose the importance of the predetermined, universal shielding electrode architectures' "interrelational-matrix" arrangement comprising at least a predetermined stacked, parallel and aligned, grouping of conductively coupled, shielding electrodes comprising at least a main-body portion 81 , each.
- shielding electrodes with main-body portion 81 will be stacked by predetermined sequencing to comprise a single, common shielding electrode structure like that of embodiment portion 4000, used for a dynamic function of electrostatic shielding and suppression of portions of energy parasitics during energized operations.
- element 806 is shown as the distance or 3-demensional area of inset and positioning that is normally predetermined as the common relative distance utilized during manufacturing to accommodate the needed insetting of the smaller electrode, main-body portion 80 of the shielded electrodes like that of 854BB and it's main-body portion 80, substantially within the registration, or area, or surface area of the larger electrode 800/800-IM's main-body portion 81 , which is also noted as the key and centrally positioned shielding electrode.
- Element 814F is the predetermined distance or 3-demensional area of inset and positioning of shielded electrode 854BBs' main-body portion 80 from the embodiment edge 817 of the whole embodiment portion 4000.
- Element 814 is the predetermined distance or 3-demensional area of inset and positioning of centrally oriented, aligned and positioned, larger shielding electrode designated herein as 800/800-IMs' own, main-body portion 81 from the edge 817 of embodiment portion 4000.
- the inset and positioning of whole shielded electrode 854BBs' main-body portion 80 and later defined electrode lead portion 812A or generally as 812"X", is relative to its position to the predetermined position of shielding electrode 800/800-IM position in an AOC as a result of a predetermined, manufacturing operation or sequence result.
- This predetermined, manufacturing operation or sequence result comprises a static predetermined electrode groupings comprising shielded electrodes and shielding electrodes.
- a shaped material portion designated as 800P comprises at least a portion of material 801 comprising predetermined properties also practicable for receiving electrode material or at least made practicable for energy portion propagation by a predetermined process such as a chemical doping or a other predetermined combination doping process or predetermined steps involving predetermined processes that leave a resulting predetermined area at least operable for conductive operations upon a material portion comprising predetermined properties.
- the predetermined electrodes, 800/800-IM and shielded electrode 854BB are shown in FIG. 1 A already disposed upon or coupled to material portions with predetermined properties 801 designated as 800P and 854BB-P (not shown), and were done as to better disclose certain aspects of the final structure combination.
- FIG. 1 A represents a fraction of the innumerable possible layout combinations of a final amalgamation of an invention as long as predetermined orientation, alignments or positions relationship rules are maintained, almost anything is practicable in terms of a final predetermined amalgam result of predetermined electrode combinations with other predetermined material portions or predetermined elements.
- the whole, planar-shaped, shielded electrode 854BB comprises at least one electrode portion designated as an electrode lead portion 812 or electrode extension 812, which is found to be co-planar with the main- body electrode portion 80 of shielded electrode 854B.
- Electrode lead portion 812 or electrode extension 812 is normally disposed or formed contiguously with the main-body electrode portion 80 by at least predetermined manner.
- Conductive-shielded electrode or shielded electrode 854BB is sandwiched between central larger, shielding electrode 800/800-IM and larger, shielding electrode 815 (not shown). Larger (this relationship is always relative to and between the two groupings of electrodes larger shielding electrode verses smaller shielded electrodes described herein), shielding electrodes 800/800-IM, and 815 are all separated from each other by a general parallel interposition of a material 801 with predetermined properties as well as between the other 800D shielding electrodes relative position to any shielded electrodes, respect position to the central larger, shielding electrode 800/800-IM and shielded electrode or energy pathway 854BB that feature a shielded electrode such as electrode 854BB with a main-body electrode portion 80 almost completely inset and immured within the two sandwiching coverage of both shielding electrode 815 and 800/800-IM, respectively that are sandwiching shielded electrode 854BB in this case, above and below, within the invention.
- the electrode lead portion 812 or electrode extension 812 is normally practicable to be oriented, aligned and positioned in a relative distance relationship as part of the whole, shielded electrode 854BB and can be utilized by when at least the smaller sized electrode, main-body portion or portions 80 of the shielded electrode 854BB is physically inset within at least one predetermined distance or area portion designated as at least 806 or 806-AOI. This relationship of inset would also be comprise within predetermined amalgamation portion of at least two same-sized (to each other) coupled common together, shielding electrodes with at least a main-body portion 81 each.
- Shielded electrode 854BB also comprises at least two additional contiguous (but, not necessarily, adjacent) portion(s) or electrode leads 79G or electrode extensions 79G, which in this case, are found as positioned by predetermined manner, directly opposite each other, to either of the North/South sides (relative per the standard page orientation of the Top being North and the bottom the South) of shielding electrode 800/800-IM or with the coupling electrode material portions 802A and 802B.
- At least one of 812s' conductive edge portion(s) (not shown) of electrode lead portion or lead extension 812 further comprised of the smaller sized shielded electrode 854BBs' main-body electrode portion 80 is operable for at least one conductive edge portion (not shown) practicable for at least one eventual, predetermined electrical circuit coupling or conductive connection attachment (not shown).
- This at least one, 812 conductive edge portion will be operable for at least one eventual, predetermined electrical circuit coupling or conductive connection attachment (not shown) that is normally located beyond a predetermined boundary portion 805 or predetermined perimeter portion 805 or a grouping edge portion 805 comprising the commonly aligned electrode edge portions of at least a predetermined stacked and parallel grouped, electrode, main-body portion 81s (not all shown) of the predetermined coupled, shielding electrodes such as 854BB.
- shielded electrode 854BBs' main-body electrode portion 80 (but for the 812 electrode lead portion) is position inset or immured within the area registries or sandwiched area or space by both shielding electrodes 800/800-IM and 815s' (not shown) electrode main-body portion 81s shielding electrode material 799, when shielded electrode 854BB is conductively coupled to conductive material portion 890A and amalgamated with at least two other predetermined shielding electrodes, the grouping will comprises at least a portion of a 3-demensional static area or space operable as 69.
- the shielding amalgamation is practicable as a single conductive structure and when, in-combination with predetermined coupled connections, to perform a combination static and dynamic shielding function operable during energized operation upon portions of energy propagating along portions of at least one predetermined pair of same-sized, complementary orientated, positioned and parallel, stack shielded electrodes, each.
- This combined static and dynamic shielding function is performed by a predetermined, amalgamated, shielding electrode structure when the inset, shielded electrode pair combinations receive a static portion of the shielding function at all times as the single, electrically common structure, specifically, and occurs in an at rest state by its static, immuring or containment, physically upon substantially all of a main-body electrode portion 80 of any shielded electrode found within a typical conditioner like 400.
- An exception would be a small shielded electrode portion (not numbered) transitioning into the predetermined electrode lead portion 812"X" that is practicable for conductive electrical connection at a point found beyond the outside perimeter , co-planar to the lead 812"X'"s main-body electrode portion from which it is integrally coupled.
- a predetermined electrode lead portion 812"X" could be to be aligned up to or against the imaginary inside perimeter of the 806 area or space as a transition portion (not numbered) becomes defined generally as now beyond the 806 portion which is normally defined as area or space located between or within, an average of the alignments 2500 of a predetermined cross section comprising both shielding and shielded electrode portions, readily definable, or just predetermined cross section a common alignment of the shielding electrodes' main-body electrode portion 81 edges and the common alignment of the shielded electrodes' main-body electrode portion 80 edges that together, help define a portion of the 806's 3-demensional perimeter within the shielding structure 4000 portion common 805.
- 69 is also operable predetermined in a dynamically operating predetermined circuit assembly portion as 69/AOI within an invention AOC operable as a contiguously . and integrally comprised portion dynamically created within the predetermined amalgamation portion of AOC comprising at least three same-sized (to each other) coupled common together, shielding electrodes.
- AOC contiguously and integrally comprised portion 69/AOI dynamically created operable within an invention AOC is always found to be within the smaller designated area relative to that total designated area a portion of which can be demarcated by at least physical, predetermined boundary 803 or a physical, predetermined perimeter portion 803 or a physical, grouping edge portion 803 of a shielded electrode like 854BB and its' main- body portion 80.
- these predetermined electrodes 854BB and 800/800-IM are positioned in a substantially parallel manner relative to each other by a desired or a needed predetermined result to be operable to these other conductive material portions like 890A for shielded electrode 854BB by way of electrode lead portion 812 and to another conductive material portion like 802A and 802B for the central shielding electrode 800/800-IM by way of electrode lead portions 79G's, respectively.
- Electrode lead portions 79G's can be conductively coupled to conductive material portions, 802A and 802B, respectively, and electrode lead portion 812A can be conductively coupled to conductive material portion 890A, all respectively.
- Application sequence of the conductive material portions 890 A, 802 A and 802B are not critical as compared to at least a stacking of electrodes manufacturing run, and can be applied or deposited or conductively couple at a later time or under a separate conductive coupling process that at least leaves the (2) 79Gs electrode portions and the 812A electrode portion conductively attached to conductive material portions 802 A, 802B and 812, respectively, operable for eventual electrical operations.
- electrode lead portion 812 is practicable for conductive coupling with, or such as but not limited to at least a conductive material portion or structures not shown but any circuit portion coupled connection that is predetermined for a specific coupling to an electrode portion practicable for using the invention embodiment in a predetermined manner.
- a shielding electrode's main-body portion 81 is not limited to just two electrode extensions 79G, but normally with a discrete multi-layered non-holed chip-embodiment will comprise at least a paired, contiguous (but, not necessarily, adjacent) portion(s) or electrode leads or electrode extensions 79G. There are exceptions, such as a contiguous common, shielding electrode extension 79G found in some hole-thru embodiment portions of commonly-owned co-pending invention variations performing propagations of energy (not shown) and is allowed.
- Shielded electrode's main-body portion 80 is also not limited to just one electrode extension 812A as an axiom as far as this position for at least contiguous (but, not necessarily, adjacent) portion(s) or electrode leads or electrode extensions 812s and a predetermined configuration needed as such is always contemplated.
- Each of these electrode lead 812, 79G or electrode extension 812, 79G is made of the same electrode material 799.
- These leads 812, 79G are simply an extension of the same electrodes and their main-body portions 80 and 81, respectively, of electrodes like that of shielded electrode 854BB and 800/800-IM, respectively all integral to a monolithic or contiguous format with each respective electrode, main-body portion 80/81.
- At least one pair of contiguous (but, not necessarily, adjacent) portion(s) or electrode leads or electrode extensions designated 812A and 812B are both practicable for conductive connection for future energized operation by operable coupling or electrical connected or are eventually conductively or electrically coupled to external terminal electrodes or electrode terminal material portions 890A and 890B for further conductive attachment (not shown) into predetermined circuitry by soldering or other commonly used conductive attachment manners like resistive fit or tension fit by conductive material portions operable for such functions, respectively, in the case of discrete versions.
- Non-discreet version of the invention embodiment portion could easily be fabricated in silicon and directly incorporated into integrated circuit microprocessor circuitry or chips. Integrated circuits are already being made comprising capacitors etched within the silicon die or semiconductor die or silicon foundation, which allows the non-discreet versions architecture of the present invention to readily be incorporated with technology available today.
- Non-discreet versions of the invention can use a coupling of electrode lead or electrode extension(s) 812 from the shielded, electrode, main-body portion 80 for the active by-pass electrode pathways to be operable or practicable for conductive amalgamation of the various predetermined active circuitry pathway (s).
- At least predetermined one portion is operable for coupling to at least one of two predetermined differential conductive portions of a predetermined circuit pathway located between a predetermined energy source and a predetermined energy-utilizing load in most cases.
- the same non-discreet version of the invention can use a coupling of electrode lead or electrode extension(s) 79G from the electrode, main-body portion 81 for the shielding electrodes or common shielding pathways electrode, main-body portion 81 to be operable or practicable for conductive amalgamation of various predetermined, common pathway(s) not of the various predetermined active circuitry pathway(s).
- shielding electrode contiguous shielding electrode lead portions 79G and the contiguous, common electrode lead portions 79G are operable for electrical operations after coupling to portions of predetermined electrical conduit or any other sort of electrical coupling interconnecting medium portion normally found physically between a energy source and an energy- utilizing load to allow operable electrical coupling or electrical connection or an electrically operable amalgamation result to allow the invention embodiment to become a portion of a predetermined common circuit.
- the invention contains a single shielding, cage-like structure 1600B or grouped commonly conductive elements that form extension and/or transformational fusion to its attached an external contiguous conductive area 314, will significantly eliminate, reduce and/or suppress E-Fields and H-fields emissions, RF loop radiation, stray capacitances, stray inductances, capacitive parasitics, and at the same time allow for mutual cancellation of oppositely charged or phased and adjacent or abutting electrical fields.
- the process of electrical energy transmission conditioning is considered a dynamic process over time.
- This process can be measured to some degree by devices such as dual port, Time Domain Reflectometry test equipment and/or other industry standard test equipment and fixtures.
- the invention can also be attached in a single, dual or multi-conductor electrical system with slight modifications made to accommodate external input and output energy transmission conductors or paths for such applications like signal, energy transmission and/or the energy source line decoupling, bypassing and filtering operations. Circuitry and depictions of some of the embodiment portions shown in this document expose some of the placements contemplated by the applicant and should not be construed as the only possible configurations of the invention elements.
- a large portion of energy parasitics will normally be found, concentrated along the smaller, shielded electrodes' outer electrode edge 803 portions of the electrode main-body portion 80s such as from 854BBs' of FIG. 1A substantially immured within the predetermined electrode, main-body portion 81 area of the commonly aligned, shielding electrode 800/800-IM with perimeter electrode edges 805 found comprising a portion of the larger shielding electrodes 855/855-IM, 845, 835, 825, 815, 800/800-IM, 810, 820, 830, 840, 850/850-IM in FIG.2A for example.
- the shielding electrodes 800/800-IM, 815, and 810 are also surrounded by material with predetermined properties 801 that provides support and an outer casing of a discrete version of an invention component.
- Both common shield termination structures 802A and 802B are conductively coupled to the same larger, shielding electrodes 815 and 800/800-IM and 810 individually and commonly conductive as a grouping, which is essential and is desired for this embodiment portion.
- termination structures 802 should be attached by standard means known in the art to the same external conductive area or to the same external conductive path (not shown) without an interruption or conductive gap between each respective termination structures, 802.
- a predetermined standard coupling means known in the art facilitates conductive connection of common shield termination structures 802A and 802B, which are attached, respectively, oppositely , on all three shielding electrode 800/800-IM, 815, and 810 (not shown) together. This act will help form a single structure to act as one common conductive predetermined, common conductive cage-like shield structure of 1600B (not shown).
- Predetermined, common conductive cage-like structure 800D mirrors single, predetermined, common conductive cage-like structure 800E except that shielded, differential electrode 855BT(not shown) contained within, is sandwiched and has a exit/entrance section 812B (not shown) with conductive material portion or structure 890B (not shown) that is not fully shielded, but in a generally opposing direction to that of conductive material portion or structure 890A and shielded electrode 854BB to join with conductive material portion or structure 890B (not shown).
- These two predetermined, common conductive cage-like structures 800D and 800E are in a predetermined, aligned and stacked positioned and parallel relationship, but most importantly, cage-like structures 800D and 800E are sharing the same, central, shielding electrode 800/800-IM, layer or pathway simultaneously that makes up each predetermined, common conductive cage-like structures 800D and 800E, when taken individually.
- predetermined, common conductive cage-like structures 800D and 800E create a single and larger conductive predetermined, common conductive cage-like shield structure 1600B that acts as a shielding electrode double container.
- Each shielding electrode double container 800D and 800E will hold an equal number of same sized, shielded electrodes that are complementary oriented and positioned to each other inset within.
- the invention when energized will operate dynamically opposing during energized operations one another within said larger structure 1600B in a generally parallel manner, respectively.
- Larger conductive predetermined, common conductive cage-like shield structure 1600B is made with co-acting 800Dand 800E individual, shield-like structures when energized, and attached to the same external common conductive path 34 (not shown), to become one electrically.
- the 1600b structure in essence, forms a minimum of two predetermined, common conductive cage-like structures 800E and 800D are required to make up a shielding, multi-functional energy conditioning device in all of the layered embodiment portions of the present invention.
- the central larger, shielding electrode 800/800-IM with respect to its interposition between the differential, shielded electrodes 854BB and 855BT(not shown) needs the outer two additional sandwiching larger (but identically sized) shielding electrodes 815 and 810 to be considered an un-energized predetermined, common conductive cage-like shield structure 1600B.
- the central larger, shielding electrode 800/800-IM will be simultaneously used by both differential electrodes 854BB and 855BT at the same time, but with opposite results, with respective to charge switching.
- a new device will have a minimum of two differential electrodes sandwiched between three larger (but identically sized) shielding electrodes and connected, external termination structures that are connected, and are conductively, as one, to form a single, larger predetermined, common conductive cage- like shield structure 1600B that when attached to a larger external conductive area 314, helps perform simultaneously, energized line conditioning and filtering functions, upon the energy propagating along the conductors sandwich within the said cage-like shield structure 1600B, in an oppositely phased or charged manner.
- the internal and external parallel arrangement groupings of a combined common conductive planes or areas will also cancel and/or suppress unwanted parasitics, electromagnetic emissions that can escape from or enter upon portions of said differential conductors used by said portions of energy as it propagates along a conductive pathway to active assembly load(s).
- shielding electrode 800/800-IM is offset a distance 814 from the edge of the invention.
- One or more portions 79G of the shielding electrode 800/800-IM extends 814 through material 801 and is attached to shielding electrode material connection portion or structure 802.
- the shielding electrode material connection portion 802 electrically connects the identically sized, shielding electrodes 800/800-IM, 815, and 810 to each other, and to all other identically sized, shielding electrodes of the filter, if used.
- the conductive-shielded electrode 854BB is not as large as the shielding electrode
- This offset distance and area 806 enables the larger, shielding electrode 800/800-IM to extend beyond the shielded electrode 854BB to provide a shield against any flux lines which might extend beyond the edge 803 of the electrode 854BB resulting in reduction or elimination of near field coupling to other electrodes within the filter or to elements external to the filter.
- the horizontal offset 806 is approximately greater than 0 to at least 20+ times or even more, dependant upon application situations, as long as the range selected allows the 806 distance, as manufactured, to be considered operable for a same-sized, but larger, sandwiching pair of shielding electrodes with main-body portion 81s.
- These shielding electrodes with main-body portion 81s are to be operable for physical and dynamic electrostatically shielding operations relative to a predetermined shielded electrode with main-body portion 80.
- the predetermined shielded electrode with main-body portion 80 singularly or as part of a predetermined grouping is normally immured within the predetermined sandwiching shielding electrode pair, as just described, and relative to shielded main- body portion 80, grouped (at least averaged uniformed spacing defined distances common 803 electrode edges) when not inset again within a sub-group that are together, inset within the at least averaged uniformed spacing defined by the electrode edge 805 perimeter that is common and used to create the 806 distance insetting relationship.
- These electrode lead portions 812 are connected to electrode material connection portion 890A which enables the shielded electrode 854BB to be electrically connected to the energy pathways (not shown) by solder or the like as previously discussed.
- element 813 is a dynamic representation of the center axis point of the three-dimensional energy conditioning functions that take place within the invention and is relative with respect to the final size, shape and position of the embodiment portion in an energized circuit.
- static elements of the an amalgamation 813 can also be further defined, relative to an imaginary intersecting or confluence point of (3) axis or components of spatial positioning relationships, such as X-axis, Y-axis and Z-axis relationship of a three-dimensional
- FIG. IB shows a portion of a cage-like shielding electrode container 800D depicted in FIG. 1A now shown in FIG. IB.
- common conductive cage-like shielding structure portion 1600B comprising common conductive cage-like structures, 800D and 800E, respectively, one immediately that sees 800D and 800E is comprising the predetermined embodiment-location relative, centrally positioned, shielding electrode 800/800-IM disposed upon material portion 800-P.
- level comprises a portion of material 801 comprising predetermined properties and conductive electrode material 799.
- substantially all of 8"XX" electrode portions of material 799 shown are disposed upon, in this case, planar-shaped material 801 portions with bottom portions 888, or portions of material 801 comprising predetermined properties with bottom portions 888 for stacking and sintering or bonding together as a single unit.
- planar-shaped material 801 portions comprise a top surface (not numbered) 845P, 835P, 825P, 815P, 800P, 81 OP, 820P, 830P, 840P, 850P are each disposed for receiving at least a portion of shielding electrode 845, 835, 825, 815, 800/800-IM, 810, 820, 830, 840, 850, etc., and of which the shielding electrodes may comprise at least one, same-sized, electrode, main-body portion 81 with electrode lead portion(s) 79G.
- shielding electrode 800/800-IM as well as shielding electrodes 815, 810 and the optional shielding electrodes 855/855-IM and 850/850-IM, as well as the shielded electrode pathways 855BB and 854BB
- the shielded electrode pathways 855BB and 854BB will all have the disposed, main electrode planar-shaped portions 81 and 80 (for 81 for the shielding electrode, and 80 for the main-body portion for the shielded, differential electrode portions) generally separated from each other for the most part by a predetermined or measured amount of a parallel interposition or deposition of a predetermined material, dielectric material or medium material 801 , which is placed or deposited during the manufacturing process between each of just mentioned conductive pathway or electrode material 799 applications or positioning.
- dielectric material portion with predetermined properties 801 or material portion with predetermined properties 801 or medium portion with predetermined properties 801 non-conductively couples and physically separates a substantial portion of the individual shielding electrodes or common pathway electrodes 830, 810, 800/800-IM, 808, 840, from the conductive pathway electrodes (not shown) sandwiched therein form one another. It is then, with locations normally found co-planar along the predetermined electrode edge portions of 805 the 79G electrode extensions or electrode leads are found operable for conductive attachment or conductive coupling to electrode material portions like 802A and 802B which are applied and amalgamated to couple all members of the predetermined grouping at some pint in a sequential manufacturing process. As described in relation to FIG.
- IB a minimum of two cages, for example 800D and 800E, which make up larger cage 1600B, are required to make up a multi-functional line-conditioning structure for use in almost all of the layered embodiments of the present invention are shown.
- Alternative conductive termination methods include applications of vertical/horizontal material layers of conductive material elements that are compatible with available and future processing technology can be used.
- structures 800C, 800D, 800E, 800F, and 800G for example as shown in FIG. IB when taken individually are comprising six shielding electrodes, 825, 815, 800/800-IM, 810, 820, 830, but when taken as separate operable shielding structures 1600A, 1600B, 1600C, one finds that individually the six same-size, shielding electrodes each with at least an electrode, main-body portion 81 825, 815, 800/800-IM, 810, 820, 830 utilized or shared together in a predetermined interweaved, overlapping manner, one will find that an operable shielding structure, 1600A utilizes same-size, shielding electrodes each with at least an electrode, main-body portion 81 800/800-IM, 810, 820, while operable shielding structure 1600B utilizes same-size, shielding electrodes each with at least an electrode, main-body portion 81 , 815, 800/800-IM, 810, while operable shielding structure 1600C is utilizing same-size,
- shielding electrode 810 is utilized by all three operable shielding structures 1600"X"(A, B, C) as just shown, thus a multiple usage of predetermined and positioned same-size, shielding electrodes each with at least an electrode, main-body portion 81, such as 810 can be utilized in a manner that covey's 810 shielding role to multiple, adjacent, and even non-adjacent, same-size, shielded electrodes each with at least an electrode, main-body portion 80, or differential active electrodes not found.
- container structures 800E and 800F for example when taken as a larger group and not individually, create a single and larger conductive cage-like shielding electrode shield structure 1600A, that acts as a double or paired shielded electrode or common pathway container. Yet, 800E and 800F also make up portions of 1600C and 1600B, respectively.
- Each container 800"X" can hold an equal number of same sized, same-size, shielded electrodes each with at least an electrode, main-body portion 80, or differential active electrodes that are not necessarily physically adjacent one another within larger structure 1600"X", yet each container 800"X” container is predetermined to be oriented in a generally homogenous physical as well as electrically parallel and common manner, respectively.
- conductive cage-like electrode shield structure 1600A with co-acting 800E and 800F individual shield-like structures when energized, and attached to the same external common conductive path area (not shown) by common conductive material connection portions 802A and 802B or by any possible means of commonly acceptable industry attachment methods such as reflux solder 777 (not shown) or conductive epoxies and adhesives and the like (all not shown), become one electrically, when energized.
- FIG. 2A an exploded, perspective view of predetermined multi-functional energy conditioner 400 is shown in FIG. 2A.
- Energy conditioner 400 combines and extends the concepts discussed in FIGS. 1 A and IB and throughout the disclosure.
- FIG. 2B is a cross- sectional view taken along a longitudinal centerline bisecting the external electrode material connection portions 890A and 890B revealing the layered architecture of the internal electrodes.
- FIG. 2C is a cross-sectional view taken along a latitudinal centerline bisecting the external common electrode material connection portions 802A and 802B revealing the layered architecture of the internal electrodes from a 90 degree rotation of the resulting cross-section as it is viewed from the same location that FIG. 2B was seen.
- Shielding electrodes 850/855-IM, 815, 800/800-IM, 810, and 850/855-IM comprising a predetermined plurality of the members of a shielding electrode groups are interleaved between a first of two predetermined plurality of members of a predetermined shielded electrode groups and a second of two predetermined plurality of the members of a predetermined shielded electrode groups.
- a first of two predetermined plurality of members of a predetermined shielded electrode groups are shown as 855BT1 and 855BT2 and a second of two predetermined plurality of members of a shielded electrode groups is shown as 854BB1 and 854BB2, and will comprise an amalgam of electrodes eventually manufactured into an amalgamated grouping of various predetermined elements.
- Additional complementary paired and positioned sets of predetermined numbers of alternating, individual members of predetermined pluralities of members of electrode groups can be further placed, positioned and oriented parallel to each other, stacked by predetermined manner within additional predetermined common, shielding electrodes that are selectively positioned as needed (not shown).
- energy conditioner 400 many variations of energy conditioner 400 are to be presented, but as such, all will comprise at least one shielding electrode 800/800-IM or similar functioning centrally positioned, shielding electrode separating the first plurality of members of the groups of shielded electrodes 855BT1 and 855BT2 from the second plurality of members of a shielded electrode groups 854BB1 and 854BB2.
- At least one shielding electrodes 810, 815 are stacked and positioned on the outermost ends covering the upper most shielded electrode 855BT1 and the lower most shielded electrode 854BB2, respectively.
- energy conditioner 400 comprises a central shielding electrode 800/800-IM disposed or formed on a layer 800P of material 801 comprising predetermined properties, which also comprises a portion of embodiment 400s' perimeter edge 817.
- Shielding electrode 800/800-IM comprises at least two electrode lead portions 79G, or electrode extension portions, which are conductively connected to common external conductive wrap around electrode material portion 802 (not shown but disclosed as an option for all invention embodiments, if applicable.) or common external, electrode material portion 802"x" or in this case, paired, common external, electrode material portions, 802A, 802B, respectively.
- These 802"x" portions can also be referred to as electrode material connecting portion(s), which conductively interconnect all shielding electrodes to each other operable for common electrical operations.
- Shielding electrode 800/800-IM comprises at least two electrode lead portions 79G, or electrode extension portions, which are conductively connected to common external conductive wrap around electrode material portion 802 (not shown but disclosed as an option for all invention embodiments
- 800/800-IM has a main-body, electrode portion 81 with electrode perimeter edge 805, which is inset from conditioner 400's edge 817 by a distance or area shown as 814.
- Shielded electrodes 855BT1 and 855BT2 are positioned above shielding electrode
- Shielded electrodes 855BT1 and 855BT2 are disposed on a layer 855BT1-P and 855BT2-P, respectively, of material 801 comprising predetermined properties and comprising a portion of embodiment 400's perimeter edge 817.
- Shielded electrodes 855BT1 and 855BT2 each comprise a main-body, electrode portion 80 and a common, shielding electrode perimeter edge portion 803, which is inset from embodiment 400 perimeter edge 817 by a distance 814F and inset from the shielding electrode perimeter edge 805 by a distance of 806-AOI, except for at least one electrode lead portion 812B, which in this embodiment 400, is merely a conductive electrode extension of main-body electrode portion 80 to the embodiment 400s' edge 817, which is also comprises of a portion of layer 855BT1-P and 855BT2-P to provide connection to external electrode material portion 890B or external conductive pathway.
- Shielded electrodes 854BB1 and 854BB2 are predetermined to be positioned inset and below, shielding electrode 800/800-IM. Shielded electrodes 854BB1 and 854BB2 are disposed on a layer 854BB1-P and 854BB2-P of material 801 comprising predetermined properties in each portion of 801 material of 854BB1-P and 854BB2-P which (801) also comprises a portion of embodiment 400s' perimeter edge 817.
- Shielded electrodes 854BB1 and 854BB2 each comprise a main-body, electrode portion 80 which is also comprising a perimeter edge portion 803, which is inset from shielding electrode perimeter edge portions 805 by a distance 806-AOI, except for at least one electrode lead portions 812B, which in this embodiment is merely an extension of main-body electrode portion 80 to the portion of the respective embodiments' material edge 817 of layer 854BB1-P and 854BB2-P to provide connection to external electrode material portion 890A or external conductive pathway. It is noted that the orientation of shielded electrodes 854BB1 and 854BB2 is 180 degrees from shielded electrodes 855BT1 and 855BT2 in an electrically complementary configuration.
- Shielding electrodes 815 and 855/855-IM are positioned and stacked parallel above shielded electrode 855BT1 and 855BT2. Shielding electrodes 815 and 855/855-IM are disposed on a layer 815P and 855P, respectively of material 801 comprising predetermined a property, which also comprises a portion of embodiment 400s' perimeter edge 817.
- Shielding electrodes 815 and 855/855-IM each comprise at least two-electrode lead portion 79G, or electrode extension portions, which are conductively connected to shielding external conductive material portions 802A, 802B that conductively interconnect all shielding electrodes together as a single common conductive structure
- Shielding electrodes 815 and 855/855-IM have main-body electrode portion
- Shielding electrodes 810 and 850/850-IM are positioned above shielded electrodes 855BT1 and 855BT2. Shielding electrodes 810 and 850/850-IM are disposed or formed on a layer 81 OP and 850P of material 801 comprising predetermined properties, which also comprises a portion of embodiment 400s' perimeter edge 817. Shielding electrodes 810 and 850/850-IM each comprise at least two electrode lead portions 79G, or electrode extension portions, which are conductively connected to common external conductive material portions 802A, 802B which conductively interconnect all shielding electrodes.
- Shielding electrode 810s and 850/850-IM each have a main-body, electrode portion 81 with perimeter edge 805, which is inset a portion of embodiment 400s' perimeter edge 817 by a distance 814, while as well as overlaps shielded electrode 854BB1 by a distance 806-AOI.
- additional pairs of shielded electrodes can be utilized by modifying and repeating the alternating shielded/shielding electrode stacking sequences or arrangements of the energy conditioner 400.
- FIGS. 2B and 2C the assembled energy conditioner 400 is shown in cross-section as previously described.
- the insetting by predetermined distance 806 of the plurality of shielded electrodes 855BT1, 855BT2 as well as 854BB1 and 854BB2, is shown in better detail.
- extension or electrode lead portions 812A and 812B are shown operable for coupling to external electrode portions 809A and 809B, respectively for electrical operation.
- the predetermined size and coverage of predetermined numbers of shielded electrodes' main-body portions 80 of the predetermined sequential static stacking order are equivalent, and the predetermined size and coverage of the predetermined shielding electrodes' main-body portions 81 are equivalent, such that they are the same size, shape, and are aligned with the predetermined edges or predetermined perimeters of their respective, shielded electrodes' main-body portions or of their respective, shielding electrodes' main-body portions members.
- shielded electrode 875R taken as a closely paired, predetermined, symmetrical shielded electrode assembly of split-paired or pairing of a predetermined split-electrode or doubled layering application, deposit or placement of electrode material 799 into predetermined, equal-sized, shielded electrode elements now called 875R-1 and 875R-2 with main-body portion 80 electrode 'twin symmetrical' portions that are separated with a very thin predetermined application or predetermined deposit or predetermined layering 814B of a material with predetermined properties 801 disposed between the first and second 'split' or doubled layering material 799 application, 799 deposit or 799 placement.
- a 875R is manufactured into the predetermined, dual layer (“split") electrode elements 875R-1 and 875R-2 as described above is achieved by subdividing the predetermined electrode application layerings from one to two cycles with a material 801 between each cycle.
- 'Split' or doubled layering material 799 application layerings for example, or whether it be a shielding, common electrode or a shielded electrode like 875R is now seen as a manufacturing technique that allows closely paired, predetermined, symmetrical twin electrodes or predetermined equal-sized electrode assembly elements to be separated by a very thin 814B spacing layer.
- This 814B layering could be different than material with predetermined properties 801, depending on properties of the 814B thin layering materials used.
- 814B is not to be confused with a thin application dimensions or deposit dimensions or layering dimensions designated as 814A which is used with the predetermined "-IM" layerings, for example, and which is also uses a predetermined spacing distance 814A, but, NOT to the degree of thin spacing between 799 materials for 814B, which is on the order of about 0.005 mil to
- 1.0 mil or as material technology improves anywhere from twice the thickness of the average of the two material 799 application layerings for the 875R1 and 875R2, for example to 1.0 mil is disclosed.
- the spacing provided by disposed material 801 with predetermined properties designated as 814C between the interleaved shielded electrode main-body portion 80s and shielding electrode main-body portion 81s noted in FIG. 4A is substantially greater, typically on the order of greater than 1.0 mil to 10 mil and even beyond those ranges, dependent upon application usages.
- a predetermined 814B distance between any of the split-electrodes could be considered normally, greater than zero to a range of 25% of the predetermined separation distance 814A normally found between, any two non-split- shielded and shielding electrodes, or the distance 814A normally found with a prior art, standard electrode spacing utilized by the manufacturers such as either PhyComp/Yageo of Roermond, The Netherlands and Taiwan or Syfer Technology, Ltd./Nova Cap/Dover Corporation of England and USA.
- various shielded and/or shielding electrodes can be predetermined and configured to utilize a significantly increased of energy portion propagation capacity of an embodiment like 400, for example, and is contemplated in all configurations of the predetermined multi-functional energy conditioner co-owned or disclosed, but only for the groups of shielded electrodes or its complementary paired differential, sub-groups of the shielded electrodes like 875R for example that are utilizing an electrode, main-body portion 80 that the 'twin symmetrical' portions of very thin predetermined application or predetermined deposit or predetermined layering 814B of a material with predetermined properties 801 is desired for.
- This configuration will provide a resulting, insignificant increase in the overall volumetric size of the predetermined multi-functional energy conditioner when comparing two units, one configured with slit-electrode technology, the other in standard embodiment shielded electrode configurations.
- split-electrode technology is also contemplated, but in all cases always predetermined as to the final make-up of any embodiments manufacture, for all shielding electrode with main-body portion 81 is desired.
- NO configurations of the center 800/800-IM common, shielding electrode or "x"-IM-common, shielding electrodes are desired.
- split-electrode-type configuration is also fully contemplated and preferred in applications of the invention where ONLY the larger, shielding electrodes with electrode main-body portion 81 (with - IM caveats in place) are configured as split-electrode configuration, however in any case all or none of the shielded/shielding electrodes should be configured in split-electrode technology, not just a haphazard, few. Another exception is that a pattern or sequencing of allowed vs.
- the resulting configuration yields a symmetrically balanced, complementary oriented, configuration of split electrodes verses non-split electrodes between sub-groups of shielded electrodes that are operable and equal in number when divided between the single, non-split, common, centrally positioned, shielding electrode 800/800-IM shielding electrode or embodiment 'fulcrum'
- Predetermined distance 814B or spacing 814B is used with split-electrode technology to allow the shielded element to increase a desired energy propagational capacity or capability over that of a single, shielded electrode, and will with a predetermined grouping of split-electrode shielded elements created for entire shielded electrode main-body portion 80s of predetermined sub-groups of complementary position shielded electrode pairs that are disclosed or found in an embodiment like 400, for example, and are contemplated in all configurations of the predetermined multi-functional energy conditioner disclosed or co-owned, elsewhere to enhance the whole, predetermined 875R shielded electrodes' ability individually, and as a part of a grouping of split-electrode shielding elements that as combined will allow a significantly increased of energy portion propagation capacity and reliability to elements by providing additional useable shielded electrode main-body portion 80, surface 'skin' (not shown) or area for such energy portion propagation situations of situation anomalies such as when unplanned or planned, voltage pulses/energy surges under unknown situations are
- FIG. 3C depicting a predetermined, amalgam of electrodes and other predetermined element portions and types that comprises at least two groups of electrodes, which in turn can be further discerned as at least three pluralities of electrodes form the two groups designated as groups 1, the larger, shielding electrodes and groups 2, the smaller, shielded electrodes.
- Groups 2, the smaller, shielded electrodes will further comprise at least two sub-groups of complementary oriented, shielded electrodes that are complementary paired.
- the elements as an amalgamation can also be further defined, relative to an imaginary intersecting or confluence point of (3) axis or components of spatial positioning relationships, such as X, Y and Z axis relationship of a three-dimensional Cartesian-like, coordinate system (not shown) which will help to determine a predetermined arrangement that allows for discerning of a complementary and balanced symmetrical amalgamated portion member that is one of 4 complementary and balanced symmetrical amalgamated portion members, each comprising one of the four quadrants, respectively of 3 -dimensional matter-occupied spatial positioning relationship that is relative to a complementary opposite or counter part positioning scheme used upon a quad-sectioned, whole complementary and balanced symmetrical amalgamated structure portion divided to a 3-axis systems' central 3-axis intersecting point common to each one of the four members of a 3-demensional, 4 quadrant system that comprise it.
- axis or components of spatial positioning relationships such as X, Y and Z axis relationship of a three-dimensional Cartesian-like, coordinate system (not shown) which will help to
- a desktop is on a X-axis and the walls holding up a ceiling in a room with the desk and its top is considered on a Y-axis
- the arm is considered on a Z-axis.
- 3C an example of an alignment of pluralities of one of two groups electrodes, the shielded electrodes that are further segregated into two complementary oriented, sub-groups of shielded electrodes with main-body portion 80, designated R and L, depicted as 875L, 875R, 865L, 865R, 855L, 855R that are shown shielded by a portion of 865, 855, 845, 865, 825, 815, and 800/800-IM, respectively, which is a good example of 'practicable or feasible balance' found among elements within a typical quadrant that, will in-turn, translate into overall complementary quadrant balance determinations.
- the determinate of the alignment 3000 of sub-groups 1 and alignment 2000 of sub-groups 2 balance found between these complementary sub-groups as to overall alignment would be taken as an average for all sub-groups 1& 2 alignments within an invention embodiment.
- the averaging of miss-alignments or area of askew 2500 is taken of 3000 position verses the 2000 position from the FIG. 3Cs' alignment sample shown, that number of the range of misalignment or area of askew 2500 could be determined to be "x" relative to the center point of the 3-axis system for one quadrant. Then the same could be done for FIG. 3Cs' (not shown) counter-part on a complementary, or opposite quadrant portion.
- the actual same-size, shielding electrodes each with at least an electrode, main-body portion 81, 800/800-IM, shielding electrode pathways 815 and 810 and use of the optional 855/855-IM and 850/850-IM shielding electrodes are all disposed into a minimum, predetermined positioning shielding-shielded relationship to each other is predicated upon a predetermined stacked sequential manufacturing operation and that results in shielding electrode pathways 800/800IM, 815 and 810 and the optional 855/855-IM and 850/850-IM same-size, shielding electrodes each with at least an electrode, main-body portion 81, when used, all respectively, formed as part of the invention by predetermined stacking manner to be physically identical to each other as members of a selected or predetermined grouping of electrodes with respect to being designated or considered members of a shielded grouping of electrodes or members of a shielding grouping of electrodes.
- FIG. 1 A and FIG. 3 Identical means to each other and only as is possible under normal manufacturing operations for such configurations to be done or achieved.
- the smaller, shielded active electrodes are being utilized by by-pass energy portion propagations 813A while the single common, shielding electrode groupings or single electrode coupled structure portions like 800/800-IM shown for both 400 and 4000 are handling the energy portion propagations designated 813B in the version shown in FIG. 1A , (which is not an array configuration.) that is practicable in certain predetermined circuit assemblies, like those shown later in FIG. 14A and FIG. 14B, to be operable as a common pathway of lower impedance for portions of propagating energies found with an energized circuit system comprising an invention circuit assembly such as those depicted in FIG. 14A and FIG. 14B.
- circuit assemblies can be utilized by when there is always to be found at least one smaller sized electrode, main-body portion or portions 80 of the shielded electrodes that will be physically inset to a predetermined distance 806 or 806"X" and others, within the a pairing of electrode, main-body portion 81 of a larger set of common, shielding electrode, main-body portion 81s' with the only exceptions being the electrode extensions 812s (if any) of at least one smaller sized electrode, main-body portion or portions 80 that are operable for eventual predetermined electrical circuit coupling or conductive connection attachment to a point beyond the common aligned perimeter edge of a stacked or parallel grouped , electrode, main-body portions 81 of coupled, common, shielding electrodes from which the 812s are contiguously and integrally comprised of.
- main-body portion 80 same manufacturing process might place an 812 lead electrode portion 799 or electrode lead portion 812 in an integral or contiguously manner at the same time or process the other 799 electrode material for the electrode, main-body portion 80 is manufactured will apply to an 812-X (not shown) non-integral or non- contiguously extension portion not placed or positioned at the same time or during the same process as the other 799 electrode material portion for the electrode, main-body portion 80.
- An 812-X portion could be applied and amalgamated later in manufacturing of the invention if that is practicable or operable for a builder of the invention and it should be noted that although not shown, this extension type is allowed, but substantially with the understanding that electrical operations that would utilize electrode, main-body portion 80 and a non-contiguous/integrally produced and coupled 812-X portion would still be conductive in a predetermined manner that would be approximately in a similar energy propagational condition of a standard 812 to be considered substantially operable.
- smaller, shielded electrode , main- body portion 80s or common, shielding electrode, main-body portion 80s can be normally defined by flat, planar shaped in surface areas for the electrode, main-body portions, 80 or 81, which is the general area that can be measured to determine the general composition of size for each respective electrode, main-body portions, 80 or 81 when and if needed.
- This electrode, main-body portion 80 or 81 areas will not include any portions considered to be of the 812 or 79G lead electrode portions or 812 or 79G electrode extension portions.
- main-body portion 81 comprising at least three shielding electrodes of any plurality of the same, found within the invention with respect to the 80 electrode, main-body portion comprising at that of at least two shielded electrodes.
- same-size, shielding electrodes each with at least an electrode, main-body portion 81 , or energy pathways with a main-body portion 81 or those marked -IM, as shown in FIG.
- 2A for example are conductively coupled or attached with the inherent central, shared image "0" voltage reference plane 800/800-IM, and will substantially increase the shielding effectiveness of an invention embodiment not only physically, but during energized operations utilizing predetermined invention attachments made earlier for the later energized circuit application.
- the sandwiching function of these outer, paired active conductive pathways with a main-body portion 81 with respect to the essential groupings of paired conductive shield-like containers 800"X" will substantially aid in total overall invention in effecting energy propagation portions in a relative manner with respect to externally attached common conductive areas and/or third energy pathway which is a common conductive area.
- offset distance and area 806 of FIG. 2A enables the shielding electrode or shielding electrode pathway 800/800-IM with a main-body portion 81 to extend beyond the complementary and balanced group alignment of electrode pathways 854BB1+854BB2 and 855BT1 and 855BT2, each with a main-body portion 80, so that shielding electrode pathway 800/800-IM is operable to provide a shield against portions of energy flux fields (not shown) which might have normally attempted to extend beyond the edge 803 of the electrode pathways 854BB1+854BB2 each, with a main-body portion 80 and 855BT1 and 855BT2, each with a main-body portion 80, but were it not for the electrostatic shielding effect of an energized faraday-like cage systems composite of grouped, coupled shielding electrode main-body portion 81 stackings or structure 4000, are practicable for the resulting reduction or minimization of near field coupling between shielded, electrode pathways the complementary and balanced group alignment of electrode pathways 854BB1+854BB2 and
- the horizontal offset 806 is approximately greater than 0 to at least 20+times or even more, dependant upon application situations, as long as the range selected allows the 806 distance, as manufactured, to be considered operable for a same-sized, but larger, sandwiching pair of shielding electrodes with main-body portion 81 s.
- These shielding electrodes with main-body portion 81s are to be operable for physical and dynamic electrostatically shielding operations relative to a predetermined shielded electrode with main-body portion 80.
- the predetermined shielded electrode with main-body portion 80 singularly or as part of a predetermined grouping is normally immured within the predetermined sandwiching shielding electrode pair, as just described, and relative to shielded main- body portion 80, grouped (at least averaged uniformed spacing defined distances common 803 electrode edges) when not inset again within a sub-group that are together, inset within the at least averaged uniformed spacing defined by the electrode edge 805 perimeter that is common and used to create the 806 distance insetting relationship.
- the 806 or 806-AOI distance for subsequent manufactured invention units could be considered to be what is not predetermined to be available but can be considered or arrived at an averaging of the plurality of 806 or 806-AOI distances created by an amalgamation of a sampling of invention units with a total number of each homogenous grouping of electrode, main-body portions.
- This 806 or 806-AOI distance method could be verified by physical cross section and can be determined to be an 806 or 806-AOI distance as well for any later invention unit batches or as a guide line used and determined to be an 806 or 806-AOI distance by the inventor, considering the many various predetermined manufacturing tolerances available.
- the electrode 809 may have one, or a plurality of, portions 812 which extend beyond the edge 805 of the shielding electrodes or shielding electrode pathways 800/800-IM, 810 and 815 by electrode extensions 812A and 812B which are in- turn conductively connected to conductive pathway material, deposit or electrode 890A and 890B respectively which enables the shielded, electrodes 855BB and 855BT to be electrically coupled to active the energy pathways (not shown) on either side electrically of shielding electrode pathway 800/800-IM.
- all additionally placed shielding electrode energy pathways designated "-IM” are normally located outside all groupings of invention electrodes to allow final sandwiching, in close proximity, of the -IM's electrodes closely, adjacent and internally positioned shielding electrode neighbor. This predetermined placement positioning is for a purpose larger than that of adding capacitance to UMPCESS embodiments.
- These additionally placed shielding electrode energy pathways are placed as a set of outer, common shielding active electrode pair(s)
- a predetermined, amalgamated, shielding, electrode structure similar to FIG. lB's 4000 structure or a predetermined shielding electrode architecture comprises an odd integer number of equal-sized, shielding electrodes, as well as, other predetermined elements and/or limitations that are predetermined to form relative, to each other, a whole in-combination invention, embodiment portion.
- the shielding electrodes are grouped as members of a predetermined groups, that are manufactured into a resulting static but predetermined, stacked, parallel alignment that includes common edge 805 perimeter alignment to each other, such that when each shielding electrode is also operable for conductively coupled by predetermined manner to each other and practicable for coupling together with a predetermined portion(s) of conductive material portion(s) such as 802"X".
- This predetermined amalgam of shielding conductors are electrically common as a predetermined whole sub-combination, and then combined by at least a predetermined process portion with other, predetermined elements and/or limitations, that together as a single, multilayered amalgamation can be combined with other externally found predetermined conductive portions as well as circuit portion predetermined elements to be considered practicable and operable for specific and unique, in terms of the simultaneous nature and mix of the dynamic energy conditioning functions operable upon portions of propagating energy under the influence to some degree of the predetermined element arrangement configured as a multi-functional energy conditioner structural embodiment, which is shown in a standard configuration, for device 400, as depicted, in FIGS. 2A-2C.
- Energy conditioner 400 comprises a predetermined amalgamated grouping of pluralities of electrodes that are segregated into a predetermined balanced and symmetrical embodiment stacking comprising predetermined relative orientation and positioning relationships both individually and as grouped relationships between members of the electrode groups all additionally relative and predicated upon a predetermined orientation and positioning relationships to a centrally positioned, shielding electrode 800/800-IM.
- predetermined pluralities of electrodes building of at least two groups of predetermined electrodes in terms of each pluralities relative size relationship to each other in terms of each of at least two types of main-body electrode portion either 80 or 81 they could be classified under.
- Each one of two groups of plurality is comprised of identical sized and identical shaped, main-body electrode portion either 80 or 81, which are at least a minimal criteria under which each respective main-body electrode portion either 80 or 81 would be classified as a groups for comprising an embodiment like conditioner 400 for it's final composition.
- Energy conditioner 400s' final material and number of elements and the resulting size and shapes as well as quantities and composition are normally dependant upon the final predetermined configuration by either a manufacturers' intent or a users' intent by purchase from a manufacturer. At least one of the two groups of a planar-shaped electrodes, the larger shielding electrodes (relative in size as a plurality to the smaller, but equally-sized members of the shielded groups of electrode main body -portions), will always total an odd numbered, integer of total shielding electrodes found within a typical invention embodiment.
- the remaining one of the at least two groups of a planar- shaped electrodes, the smaller shielded electrodes, (relative in size as a plurality to the larger, but equally-sized members of the shielding groups of electrode main-body portions), will always total to an even numbered, integer of shielded electrodes found in almost any amount within a typical invention embodiment.
- the two groups of pluralities of electrode main-body portion 80s are divided, paired, oriented complementary to each other as they are segregated onto at least two predetermined groupings of predetermined pluralities of predetermined electrode main- body portion 80s available, while the larger, equally-sized members of the remaining one of two groups of electrodes will be of the shielding groups and in embodiment 400 comprises in this instance same-sized and same-shaped members that can include shielding electrodes 850/855-IM, 815, 800/800-IM, 810, and 850/855-IM, as shown.
- electrode leads, 79Gs or 812"X"s or similar are specifically called out or designated with the following words, singular or plural, the applicants' usage of specific element words of: electrode(s), conductor(s) energy pathway(s) are generally relegated to mean these respective specie members' specific type of planar-shaped, main-body portion of conductive material which is disposed or formed as such and found herein.
- 'shielded' or 'shielding' when these terms are used in- combination with, and/or are referring specifically and respectively to the static and dynamic function received or performed upon as a member of an identically-sized and identically-shaped plurality of element members of one of the two groups of electrode elements designated as operable to either a 'shielded' or 'shielding' function both statically and dynamically (in energized operations) as each is relatively comprising at least a main- body electrode portion 8"X".
- FIG. 2A An exploded, perspective view of predetermined multi-functional energy conditioner 400 is shown in FIG. 2A. Energy conditioner 400 combines and extends the concepts discussed in FIGS. 1 A and IB and through out the disclosure.
- the horizontal 806 or 806-AOI area/distance can be stated as approximately between 0 to 20+ times the vertical distance 806 or 806-AOI between the electrode pathways 855BB and 855BTs' respective main-body portion 80 the shielding electrode or shielding electrode pathway 800/800-IMs' respective main-body portion 81.
- This offset distance 806 or 806-AOI can be optimized for a particular application, but all distances of main-body portion 81s's overlap of the main-body portion 80s yield a predetermined 806 or 806-AOI distance (and others) among each respective pathways main-body portion that are ideally, approximately the same with in an invention embodiment as predetermined manufacturing tolerances allow.
- the 806 or 806- AOI distance for subsequent manufactured invention units could be considered to be what is not predetermined to be available but can be considered or arrived at an averaging of the plurality of 806 or 806-AOI distances created by an amalgamation of a sampling of invention units with a total number of each homogenous grouping of electrode, main- body portions.
- This 806 or 806-AOI distance method could be verified by physical cross section and can be determined to be an 806 or 806-AOI distance as well for any later invention unit batches or as a guide line used and determined to be an 806 or 806-AOI distance by the inventor, considering the many various predetermined manufacturing tolerances available.
- the directional orientation of the two predetermined groupings of electrode, main-body portions, respectively can be switched such in final length to width orientations, that for example 802A and 802B electrode material coupling portions are now located 'east and west' (relative to their positioned 'north and south', as shown in FIG. 1A, for example), while 890A and 890B electrode material coupling portions that could be located 'north and south' (relative to their positioned 'east and west', as shown in FIG. 1 A , for example) and placed in a predetermined circuit and predetermined to be coupled in the same electrically attached, respective manner as FIG 14A or FIG. 14B.
- 802 A and 802B electrode material coupling portions to still utilized in a non-primary energy propagational pathway usage that was shown utilized by 802A and 802B electrode material coupling portions in the same electrically attached, respective manner as shown utilized FIG 1 or FIG. 6A.
- the electrodes utilized in an active, primary energy propagational pathway usage will always maintain any, one, l A, of a pairing of smaller, main-body portion 80 inset within than any one, of the larger main-body portion 81 electrode performing a shielding function, both physically and electrostatically during energization in a FIG. 14A predetermined circuit scheme or similar.
- the invention is fully operable for the primary shielding function of electrostatic shielding used very effectively for conditioning portions of energy as the applicant is disclosing and as the applicant is contemplating.
- Predetermined distances or areas 806, 814 and 814F which are outlined by the various predetermined alignments of selected or predetermined perimeter portions of various electrode and material elements that can make up a predetermined cage-like shielding electrode structure.
- These defined areas that use perimeters include, but are not limited to electrode, main-body portion 81 of all of the shielding electrodes found comprising a common, shielding electrode structure like 4000 in FIG. IB and which will normally utilize this type of placement positioning of the common, shielding electrode structure in a predetermined, relative manner, with respect to the area or distance dimensions that are normally predetermined or found with respect to the smaller, uniformly inset, shielded, electrode, main-body portion 80 of the shielded, electrodes, shown in FIG. 2 A.
- a physical, Faraday cage-like effect or a physical, electrostatic shielding effect function with electrically charged containment is used upon portions of external and internally generated, energy parasitics, portions of which are found propagating upon the various, smaller, shielded electrodes.
- These active conductive energy pathways will normally have concentrations of these energy parasitics located near the 803 electrode edges of the shielded, electrode, main-body portion(s) 80 that are now contained or immured from escape by the predetermined inset distance parameters relative to the shielding electrode, main-body portion(s) 81 that substantially prevent escape of local energy parasitics as well as substantially preventing entry of foreign or non-localized energy parasitics created elsewhere and the coupling of either groups of energy parasitics to the same shielded, electrode, main-body portion(s) 80, in the case of foreign parasitics, that are substantially prevented from entry) adjacent, shielded, electrode, main-body portion(s) 80 neighbor(s).
- This active, electrostatic parasitic control system is substantially the result of a combination of predetermined limitations or requirements of specific elements that included, but are not all limited to:
- the portioned amount and predetermined number of specific materials, elements and particularly predetermined numbers and arrangements of the various electrodes are normally evenly, or are balanced or divided between and positioned in a predetermined manner on opposite sides of the critical, centrally positioned shielding electrode 800/800- IM and its' electrode, main-body portion 81.
- variations of the minimum invention are certainly practicable to be operable for receiving, additional shielding electrode energy pathways that include the electrode, main-body portion 81 surrounding of the combination of a shared centrally positioned conductive energy pathway 800/800-IM surrounding a predetermined grouped, predetermined placement of center conductive energy pathway and a predetermined plurality of paired, smaller by -pass or shielded electrodes with at least one main-body portion 80 created during manufacturing or employment of the invention to be able to exploit the increased inherent electrostatic shielding function created during energization by a predetermined optimized conductive attachment or coupling of the Faraday cage-like electrodes' main-body portion 81 comprising a substantial material portion of the single shielding structure.
- the Faraday cage-like electrodes' main-body portion 81 comprising a substantial material portion of the single shielding structure to also be practicable to facilitate surge dissipation to within and/or to any external common conductive area portion or common energy pathway portion
- the shielding electrode structure is operable in its attachment to be considered electrically operable or conductively coupled to these portions in a predetermined, common manner to provide an increase or enhancement of not only a low impedance effect of the common, shielding electrode structure and its' external common conductive area portion or common energy pathway portion, but its' use as a primary routing pathway beyond an invention AOC, itself, which is not considered part of the active, smaller, shielded electrode pathways, as found within the AOC for many of the invention embodiments.
- Energization of area AOI-69 zone of (2) various identical embodiments when compared as a whole structure with their various amalgamated predetermined invention elements will have siimalar dynamic relationship characteristics to each other for the various energy portions and propagational confluences that will allow (usually in terms of either observable or measurable or lack of observable or measurable) a repeatable and sustainable, optimized, or harmonious or even a 'least, disruptive' dynamic confluence or complementary energy portion inter-actions (that could include mutual energy portion coupling and/or cancellation or enhancements) within the comparative invention embodiments in predetermined configurations that will be measured substantially the same relative to each other and each relatively measured against a co-owned, Norm/Standard with the preferred configured AOI-69 zone elements when it too, is also placed into an identical predetermined circuit configuration and energized for measurement standard to which the various embodiments as depicted and that could be compared to.
- Connection of the internally placed shielding electrodes with one another and the external energy pathway not of the at least two differential conductive pathways can be used a as a non-active energy pathway that can provide a reference voltage to the circuitry contained within the invention that allows for predetermined low impedance pathway utilized by the respective portions of the differential pathway propagating energies to utilize in a complementary and balanced manner with respect to one another and to the benefit of the circuit system efficiency over that of similar prior art circuitry.
- the invention architecture when combined in a predetermined manner with separate and multiple circuitry pathways for energy propagation will allow portions of energies propagating along the contained circuitries a jointly and simultaneously shared ability for portions of these energies to utilize a third but common energy pathway created by the common interconnection of the shielding electrode pathways into a shielding structure along with this shielding structures external conductive attachments to the same electrically potentialed common conductive area or pathway not of the differential energy pathways.
- This separate but common and commonly shared third pathway acts as not only a voltage divider for energies found in predetermined energized circuitry, but due to its actual physical and electrical placement locations in a normally larger energized circuitry.
- This physical and electrical location can best be described as a shielding interpositioning and electrically common placement between at least a set of paired and oppositely co-acting, differential conductive energy pathways during energized operations.
- the separate third pathway also becomes simultaneously utilized and shared as a common voltage reference node with respect to not only the multiple circuits operating within the invention and /or its AOC but at least a set of paired and oppositely co-acting, differential conductive energy pathways of the same circuit during energized operations, as well.
- the various energy conditioning functions performed by the invention in- combination with other predetermined elements when coupled into a predetermined circuit for predetermined energized operation will also depend upon the predetermined coupling or attachment choices made for the predetermined attachment portions operable of invention elements that are methodologies employed by a user.
- At least a predetermined portion of one or more of the various energy conditioning functions derived by the inventions' operation as part of a predetermined circuit or predetermined application in a predetermined energized operation can be measured or observed by predetermined placement within a predetermined test circuit or even tested as part of an actual predetermined application circuit portion.
- the 'invention+predetermined elements that are in-combination' are practicable to form an embodiment that is operable for a portion of confined, groupings of dynamic relationships at least taking place between/amongst propagating, energy portions that are utilizing portions of the invention+ predetermined elements, in-combination.
- predetermined spatial relationships or limitations such as predetermined distance-relative proximities, predetermined relative-positional orientations, as well as, predetermined material compositions and intermixed positionings are all substantially related to these various predetermined material portions and the invention that comprise the final structure, that will be amalgamated as the predetermined relationships within the invention to combine from these parts into a whole static structure and will be responsible in substantial part to the results received by a new user to the invention as compared to any other possible non- owned, prior art device by the manner and effect upon dynamic energy propagations, confluence, conditioning and interplay a predetermined area of interaction(s) (AOI) or local within the invention
- AOC portion plays with a predetermined and energized, circuit portion.
- the aligned, the invention is dependant upon predetermined, symmetrical balanced arrangements of the invention elements that are predetermined in both how they are arranged and positioned on either side of a centrally positioned shielding electrode.
- the inventions' portioned balance, dynamic function is dependant upon what the static structure result reveals and is always dependant upon predetermined static structural AOC balance and static structural AOC symmetry in element portions of materials, positionings, shapes, thickness or sizes, shielding.
- Portioned balance is a dynamic function the invention offers to active load within an operating circuit.
- the inventions' portioned balance, dynamic function is dependant upon what the static structure arrangement result will reveal at energization and the predetermined static structural AOC balance and static structural AOC symmetry in element portions of materials, positionings, shapes, thickness or sizes, shielding as well as the static conductive coupling arrangement when the device is energized is more determinant in the quality of the portioned balance dynamic function in terms of the resulting dynamic AOI balance/symmetry than it is the other external circuit assembly portions found beyond the AOC.
- FIG. 4 is a cross-section view of device 399 which is a predetermined, stacking sequence of a currently owned multi-layer, shielding electrode architecture with differential shielded electrodes with various predetermined selected areas distance relationships between predetermine electrodes and other elements.
- FIG. 4A presents 69 as an ideal AOI.
- 69-AOI is the area recognized statically, as well as dynamically, where the unique energy conditioning is practicable to take place simultaneously within this area and cannot be repeated identically without this type of arrangement, according to at least the prescribed disclosed herein.
- a predetermined positioning and predetermined static sequence arrangement of each individual electrodes' main-body portions, 80 and/or 81 is in its relative final positioning to or from the other adjacent, individual electrodes' main-body portions, 80 and/or 81 and their own, predetermined positioning sequence has been created; the predetermined, from all direction, distance arrangements of each individual electrodes' main-body portions, 80 and/or 81 edges, relative to the predetermined distance arrangements of to, or from, the other electrodes' main-body portions, 80 and/or 81 edges or edge groupings of electrodes' main-body portions, 80 and/or 81 edges; the predetermined, (relative to and/or from many, predetermined directions), distance arrangements of each individual electrodes' relative predetermined, (relative to and/or from many, predetermined directions), distance arrangement to or from the final invention physical AOC boundary or casement 817 edges, if applicable; the predetermined numbers of electrode element groups of the various groups of (shielding and shielded) electrodes are present; the predetermined numbers of electrode element groups
- the total shielding electrode structure possesses a balancing effect to the contained, same-sized, shielded electrodes each with at least an electrode, main- body portion 80, or differential electrodes that will with predetermined circuit attachment of the invention at energization be both practicable and operable to allow both complementary and simultaneous either full for partial electrostatic shielding of portions of propagating energies.
- the final integer number of shielding electrodes will always be an odd-numbered integer equal to or larger than 3. In all embodiments, the final integer number of shielded, electrodes will always be at least an even-numbered integer equal to or larger than 2. In all embodiments, the final integer number of shielding electrode cage-like structures 800"X" will always be at least an even-numbered integer equal to or larger than 2. In all embodiments, the final integer number of shielded, electrodes + number of shielding electrode cage-like structures 800"X"+ number of shielding electrodes will always be at least an odd-numbered integer equal to or larger than 7.
- grouped electrodes were conductively interconnected by an external electrode band such as 809A, 809B for differential electrodes and 802A and 802B for common, shielding electrodes.
- an external electrode band such as 809A, 809B for differential electrodes and 802A and 802B for common, shielding electrodes.
- one or more of the grouped electrodes are inset from the external electrode band such that it is "floating", or not directly connected by a terminal or lead portion.
- FIGS. 5A-5D alternate embodiments of the present invention are shown including the use conductive vias 1000 to conductively interconnect two or more electrodes of a single electrode grouping.
- the vias 1000 extend perpendicularly through the material separating the electrodes to conductively connect the electrode groupings.
- a common, shielding electrode 815 positioned on material 815P includes electrode lead portions 79G for electrical connection to other common, shielding electrode groupings (not shown).
- a second common, shielding electrode 815BF, formed on material 815F1P is positioned directly below common, shielding electrode 815 by a distance 814A.
- Second common, shielding electrode 815BF does not include electrode lead portions 79G and is considered to be 'floating'.
- Vias 1000 are used to provide a conductive pathway through material 815P to allow common, shielding electrode 815BF to have an electrical connection to not only common, shielding electrode 815, but also other common, shielding electrode groupings. The concept is further shown in a cross- sectional view with regard to FIG.
- FIG. 5B which is identical to FIG. 2B except that common, shielding electrode 815BF is shown inset from common, shielding electrode 815 by distance 804 and from embodiment edge portion 817 by distance 804C and vias 1000 are shown conductively connecting common, shielding electrode 815BF to common, shielding electrode 815.
- the concept is also applicable to differential electrode groupings as well and is shown in FIGS. 5C and 5D.
- differential electrode 855BT-1 is sandwiched by floating differential electrodes 855BT1-AF and 855BT1-BF.
- Vias 1000 are used to conductively connect the smaller floating differential electrodes 855BT1-AF and 855BT1-BF to differential electrode 855BT-1.
- each differential electrode extends to the end of their respective support plate material for conductive connection to an external electrode band (not shown).
- the conductive interconnection of differential electrode grouping 403B is supplemented by vias 1000 with allow alternate conductive interconnection pathways within the differential electrode grouping 403B. It should also be noted that vias 1000 also enhance the structural integrity of the attached electrode groupings and of the energy conditioner as a whole.
- the predetermined multi-functional energy conditioner 506 shown in FIG. 7A and 7B is identical to predetermined multi-functional energy conditioner 505 of FIGS. 6 A and 6B except that the outer shielding electrodes 850/850-IM and 855/855-IM have been eliminated. This predetermined configuration will still maintain the shielding integrity provided predetermined shielding electrode structure's electrostatic shielding functions used upon the predetermined groupings of shielded electrodes.
- the predetermined multi-functional energy conditioner 501 shown in FIGS. 8 A and 8B is identical to predetermined multi-functional energy conditioner 400 of FIG. 2B and 2C except that two additional predetermined common, shielding electrodes 800T and 800B have been added. Common, shielding electrode 800T is positioned above shielding electrode 800/800-IM and shielding electrode 800B is predetermined to be positioned inset and below shielding electrode 800/800-IM.
- Predetermined shielding electrodes 800T and 800B are generally parallel and predetermined when stacked in a predetermined sandwiching manner relative to shielding electrode 800/800-IM. It is also noted that predetermined shielding electrodes 800T and 800B
- shielding electrode 800B comprise a predetermined and smaller main-body electrode portion 80 such that each is inset equally with respect to shielding electrode 800/800-IM.
- 800B helps reduce commonly located stress concentrations that form aligned stacked vertically over each other with normally identically aligned, main-body electrode portion 80s' electrode edges during operation of the energy conditioner within a predetermined circuit.
- Predetermined insetting of various predetermined electrodes also serve the purpose of producing material stresses on portions of material 801 comprising predetermined properties that could be of a dielectric material that would other wise be vulnerable to develop in certain instances, stress damage that would possibly concentrate along perimeter or electrode edges 805 or 803 respectively, in certain predetermined electrodes stacking sequences that would result in an embodiment like that shown in FIGS. 5C thru 1 IB where the results of certain predetermined, electrodes stacking sequences beyond two identical groups members as shown in FIGS. 5C thru 1 IB and specifically, like 855BT1-ASB, 855BT1 and 855BT1-BSB of FIG. 5C for example, are not respectively adjacent or sandwiched by at least a normally interposing shielding electrode.
- predetermined multi-functional energy conditioner 502 shown in FIGS. 9A and 9B is identical to predetermined multi-functional energy conditioner 501 of FIGS. 8A and 8B except that the shielded electrodes 855BT-2 and 854BB-2 had been replaced by smaller shielded electrodes 855BT-2S and 854BB-2S which are of a smaller main-body electrode portion 80 such that they are inset from the rest of the shielded electrodes as the shown in FIG 9B.
- the insetting of the electrodes helps reduce stress concentrations at the electrode edges during operation of the energy conditioner.
- the predetermined multi-functional energy conditioner 503 shown in FIGS. 10A and 10B is identical to predetermined multi- functional energy conditioner 501 of FIGS. 8A and 8B except that the outer shielding electrodes 850/850-IM and 855/855-IM have been eliminated.
- the predetermined multi-functional energy conditioner 504 shown in FIGS. 11 A and 1 IB is identical to predetermined multifunctional energy conditioner 502 of FIGS. 9A and 9B except that shielded electrodes 855BT-2S and 854BB-2S are not only of a smaller main-body electrode portion 80 such that they are inset from the rest of the shielded electrodes as the shown in FIG 9B, but they are also of a smaller length such that they are inset from the rest of the shielded electrodes as the shown in FIG 9A. Accordingly, three of the four shielded electrode edges of shielded electrodes 55BT-2S and 854BB-2S are inset from the shielded electrode edges of the remainder of shielded electrodes 55BT-1 and 854BB-1.
- shielded electrodes 855BT1-AF, 855BT1, and 855BT1-BF were interconnected with paired, conductive vias 1000 or paired internal, electrode coupling portions 1000 which are operable for common electrical coupling or as electrically common connection of otherwise, 'floating' shielded electrodes 855BT1-AF and 855BT1-BF, respectively to shielded electrode 855BT1.
- Shielded electrodes of 855BT1-ASB, 855BT1, and 855BT1-BSB using the normal, designated 890"X"-type, coupling connections or attachments could also make use of the at least paired, conductive vias 1000's (or the at least paired, internal, electrode coupling portions 1000), internal electrode portion interconnecting function for providing additional structural integrity beyond that of the horizontal support function offered support function offered by the 801 material portions' layering.
- Paired, conductive vias 1000 or paired internal, electrode coupling portions 1000 would offer and provide a vertically secured internal electrode portion interconnecting function provided in addition to that horizontal support function offered by adjacent material 801 to these respective electrode portions found within a predetermined multifunctional energy conditioner like 403. It is noted that the actual methods used to form or dispose of the paired, conductive vias 1000 or paired internal, electrode coupling portions 1000 between any respective electrodes or the coupling of units 1000 to each electrode are disclosed to be claimed, only the result is disclosed to be claimed by the applicant in combination with co-owned universal cage-like common, shielding electrode shielding structure and other elements, as disclosed.
- FIGS. 12A and 12B an alternate embodiment to the shown in FIGS. 12A and 12B.
- the predetermined multi-functional energy conditioner 506 shown in FIGS. 12A and 12B is identical to predetermined multi-functional energy conditioner 400 of FIG. 2B and 2C except that the energy conditioner 506 has 'floating' shielded electrodes 855BT1-AF and
- 855BB1-AF which are electrically connected to shielded electrodes 855BT1 and 855BB1, respectively, by a plurality of paired, conductive vias 1000 or paired internal, electrode coupling portions 1000.
- paired, conductive vias 1000 or paired internal, electrode-coupling portions 1000 are used with both shielded electrodes and shielding electrodes.
- the predetermined multi-functional energy conditioner 507 shown in FIGS. 13A and 13B is identical to predetermined multi-functional energy conditioner 506 of FIG. 12A and 12B except that shielding electrode 815 is electrically connected by a plurality of paired, conductive vias 1000 or paired internal, electrode coupling portions 1000 to a 'floating' common, shielding electrode 815BF and that shielding electrode 810 is electrically connected by a plurality of paired, conductive vias 1000 or paired internal, electrode coupling portions 1000 to a 'floating' common, shielding electrode 810TF.
- predetermined non-heterogeneous insetting relationships normally found within an embodiment such as FIG. 2As; embodiment 400, a combination of predetermined non-heterogeneous insetting relationships with the usage of paired, conductive vias 1000 or paired internal, electrode coupling portions 1000 enhancements that are also providing a vertically secured, internal, electrode portion interconnecting function that is well suited for certain circuit assembly configurations where usage of an isolated third energy pathway is not possible and where the need to utilize the larger shielding electrodes as direct feed-thru conductors in anyone direction, makes this configuration well suited for that type of circuit assembly.
- FIG. 14A and FIG. 14B which shows a basic circuit assembly or circuit arrangement 6900 that is practicable for simultaneously maintaining operable interaction between (3) electrically isolated, energy pathways that will yield sustained and harmonious energy portion confluences and interactions.
- Portions of energies utilizing these predetermined (3) energy pathways are depicted in FIG. 14A and 14B as energy-in pathway 303, energy-return pathway 309, and third energy pathway and voltage reference 314 with optional vias 315 or low impedance energy pathway and voltage reference 314 with optional vias 315, respectively.
- circuit assembly 6900 which is not the only circuit assembly foreseen or allowable, by the applicant.
- circuit portions and components could be coupled and utilizing portions of the (3) energy isolated pathways as just said, along the way to other elements and componentry will be contemplated by the applicant.
- These circuit assemblies or just circuit portions can include, but will not be limited to; energy distribution networks, data or signal energy networks; all of which can comprise a multitude of possible circuit assemblies configurations that are operable or practicable for conditioner 400 inclusion.
- FIG. 14A shows an energized circuit portion 6901 of FIG. 14B comprising an embodiment 400 of FIG. 2A, 2B and 2C, or even any one of the predetermined electrode layered embodiments, disclosed herein, as well as the co-owned embodiments disclosed in other filings, that are known as the discrete versions of predetermined electrode layered embodiments practicable or operable for sustained circuit energy conditioning, (co-owned embodiments are not shown) .
- the energized circuit portion of a larger electronic circuit application operating with this circuit assembly as a whole, or as at least with this circuit assembly configured could easily have 6901 as a component test fixture or component test circuit (both specifically not-shown).
- the energized circuit portion 6901 will be operable for a unique, multi-functional, simultaneous energy conditioning combination function that is only found in an energized result unique of the disclosed, with these predetermined electrode layered embodiments or with the other previously disclosed embodiment members comprising this family of predetermined energy conditioning and shielding electrode structure embodiments in combination with other predetermined elements.
- Multi-functional, simultaneous energy conditioning combination function results from predetermined coupling or attachments of an energy conditioner like 400 operable for conductive attachment with predetermined circuit portions that when energized can be observed by predetermined measurement operations elsewhere, performing the same type of energy conditioning upon portions of energies that include, but are not limited to, at least predetermined portions of sustained, common mode and differential mode energy filtering utilizing predetermined internal, capacitance characteristics manufactured by predetermined manner, as part of a finished structure like 400.
- the circuit portion 6901 is a coupled passive energy conditioning network that is part of a larger circuit assembly 6900 and is utilized in an energized manner after operable attachment or coupling of predetermined conductive material coupling portion(s) 315 are made for predetermined conductive portion conductive coupling of conditioner 400 an application of predetermined conductive material coupling portion(s) 315 applied by standard means of attachment or method operations known in the art such as soldering, mechanical coupling techniques such as resistive fit, tension fit or other standard means of attachment or attachment method or operations known in the art.
- standard means of attachment or method operations known in the art
- mechanical coupling techniques such as resistive fit, tension fit or other standard means of attachment or attachment method or operations known in the art.
- any embodiment disclosed herein, as well as any of the same family members of the other, co-owned embodiments previously disclosed are practicable to be made operable by a predetermined manner for usage during predetermined electrical operations.
- This usage can comprise predetermined and conductively coupled, conductive material structure pairs 890A and 890B each conductively attached by material 315 to either first or second energy pathway, respectively as long as either one of conductive material structure pairs 890A and 890B is coupled to an external conductive portion 304 or 310 respectively.
- Contiguous wrap-around (if used but not shown here)central shielding electrode material portions 802 or the separate 802A and 802B or 802"x" portions are practicable for conductively coupled connection by electrode connection material portions such as 315 material to contiguous conductive planar portion 314 so that a combined physical and dynamic shielding function is operable at energization relative to providing the combined static and dynamic shielding function simultaneously to portions of energy propagations located along portions of the internally located (within 400), and shielded complementary oriented/positioned, bypass electrode pairings, which are also respectively, conductively coupled to electrode material portions 890A and 890B.
- Electrode material portions 890A and 890B are coupled to energy pathways 303 and 309, respectively, each isolated between the third conductive pathway provided by the electrically coupled electrode material portions 802A, 802B, then by electrode connection material portions 315 to contiguous conductive planar portion 314 and on, if needed to 315 conductive via portions to common conductive area predetermined (not shown) or a operable portion utilized as a common conductive portion (not shown) operable for common circuit voltage referencing (not shown) relative to the circuit assembly 6900's' dynamic operations and elements that are operating.
- This third pathway can also be any other common conductive portion operable for providing the same common circuit voltage referencing function like an area (not shown) coupled to optional chassis or earth ground , in some cases.
- the conductive coupling as described for the predetermined portions and the circuit pathways 303 and 309 are practicable to provide portions of propagating energies found within the circuits, a alternative, low impedance node or third pathway that is not by way of direct conductive connection from either first energy pathway 303 (energy-in pathway 303) or second energy pathway 309, (energy return pathway 309) or any direct conductive connection or alternate energy-return pathway.
- This third pathway when conductively coupled to embodiment 400 during energized operations provides or allows a low impedance pathway alternative for detrimental energy portions or circuit energy portion disturbances, such as circuit noise, , an alternative, low impedance node or third pathway as an additional routing for propagation. It can also provide return of detrimental energy portions or circuit energy portion disturbances, such as circuit noise to back to a source as described in Kirchoff s Law that is not needed 301 as an alternative, low impedance node or third pathway as an additional routing for propagation.
- This third pathway is also operable because of the coupled, shielding, common electrode structure like a portion of 4000 of FIG. IB and FIG. 2 A that is comprising at least shielding, common electrodes with main-body portion 81 coupled together and operable as a single structure portion with conductive attachment to conductive portion 314 as part of a internal conductive extension of an external common conductive area such as contiguous conductive planar portion 314 and its coupled pathways , beyond.
- the third energy pathway is isolated from contiguous electrical attachment to 303 and 309 energy pathways and is operable as a common pathway of least impedance for portions of complementary, propagating energy portion field flux that appear as a result of circuit 6900s' energization, and will also provide energy pathway blocking functions, surge portion suppression functions , as well as facilitate close propagations of complementary and mutual coupling of propagating energy portions that result in mutual cancellations.
- An instantaneous, sustained complementary, dynamic polarity charge switching function is operable for a predetermined dynamic circuit operation and will comprise part of the electrically common shielding electrodes' dynamic operations, aid in circuit energy portion decoupling of dynamic propagations, as well as, complementary energy portion bypass operations which are all operable and influenced to some degree directly as a result of the presence of a third energy pathway portion, not of the other two energy pathway portions 303 and 309 (which are in electrically complementary or opposite operation with respect to each other and simultaneously) with an apparent, identical internally provided mutual voltage reference found along the shielding, third energy pathway adjacent to each of the remaining shielded portions of energy pathways.
- a voltage dividing function is also available and can be used in an energization after a predetermined coupling comprising embodiment 400 is made into circuit portion 6901, as part of circuit assembly 6900.
- the voltage within the embodiment will be found to be effectively one-half as much of the original voltage portion of the circuit located respectively on opposite sides and of the central shielding, common electrode 800/800-IM or energy pathway portion 800/800-IM comprising circuit portion 6901.
- the isolating and shielding effect of a common conductive portions of the invention embodiment can be operable for dividing the circuit voltage in half. Utilization of this function provides a user a manner in which to minimize the internal stresses or hysteresis effect commonly found with prior art components.
- Embodiment element material hysteresis effect, as well as other material- "memory” stresses is recognized as debilitating and undesirable within prior art components, and will be little or substantially absent as an energy sapping influence in a new invention embodiment material or elements comprising the invention 400 for example.
- Hysteresis effects and stresses will not play a substantial role in the overall ability of an invention device in its operable dynamic ability to facilitate efficient, energy portion propagation, conditioning or energy portion confluence occurring within the AOC to any noticeable degree in a circuit assembly like 6900.
- the energized circuit portion 6901 found in FIG. 14A and 14B comprises energy source 301 that starts the energy portion propagations into a circuit 6900, energy source 301 conductive coupling portion 302 which is physically coupled to external energy pathway 303 which in turn is conductively coupled to predetermined, external conductive area or portion 304 to facilitate alignment, support and further optimal operability of 400 to circuit portion 6900.
- External conductive area or portion 304 can also comprise additional pathway elements to load 301 that could include an internal electrode connection material portion or VIA 315 or almost any conductive medium between the remaining portions of pathway 303 which can be wider, narrower, shorter, longer, on the surface of substrate portion 316 or imbedded within multi-layered substrate portion 316B (not shown) by predetermined manner to couple conductively to energy-utilizing load 301.
- additional pathway elements to load 301 could include an internal electrode connection material portion or VIA 315 or almost any conductive medium between the remaining portions of pathway 303 which can be wider, narrower, shorter, longer, on the surface of substrate portion 316 or imbedded within multi-layered substrate portion 316B (not shown) by predetermined manner to couple conductively to energy-utilizing load 301.
- energy portion propagations return once again into a circuit 6900, from energy utilizing load 307, along coupled, conductive coupling portion 308 which is physically coupled in most cases to, external return energy pathway 309 which in turn is conductively coupled to at least a predetermined, external conductive area or portion 310 and on to 311 and the remaining 309 energy pathway portion to facilitate alignment, support and further optimal operability of 400 to circuit portion 6900, if needed.
- a solid shaped area or conductive material-mounting pad, 304 and 310 or pad material is desired for conductive connection of conductive material or conductive structures 890A and 890B.
- the conductive material mounting pads or pad materials 304 and 310 utilized by the conductive material structures 890 A and 890B are for mounting and facilitating structural support and conductive connection of into the differential circuit portions 304 and 310 with solder material or the like 315 which is already utilized by prior art.
- a third energy pathway normally could comprise (2) separated pad configurations
- contiguous pad 314 or conductive area 314 is almost always preferred for mounting and facilitating structural support and conductive connection of the monolithic wrap-around-type conductive structure 802 or multiple, paired structures like 802A and 802B soldering attachments for third pathway operations.
- Contiguous pad 314 or conductive area 314 along with conductive VIA or connection medium portions facilitate a static pathway 314-315 to further grounding or reference like a chassis ground or earth ground 313, if desired.
- a larger, energy portion propagation network can easily comprised of a predetermined portion of the energized circuit assembly 6900 will comprise a low impedance energy pathway.
- the various electrodes comprising three groupings of common, shielding electrodes are significantly differentiated by the relationship of the size ratios or predetermined sized comparison of each respective electrodes' main-body portion 81 or main-body portion 80 to each other, adjacently as individual electrode, main-body portions or as groupings of single or individual shielding electrode, main-body portion 81s to groupings of single or individual shielded electrode, main-body portion 80s, as well as, their respective orientation directions and their final functionally based on predetermined circuit attachment positions and couplings and subsequent energization.
- the parallel movement of complementary propagating energy portions along found moving mutually opposed along portions of the 303 and 309 energy pathways are practicable to receive operable energy conditioning functions as well as and operable electrostatic shielding effect in which an energy propagation portion operating on one side of the central common and shared conductive energy pathway and the coupled external area 314/315 to chassis ground 313 or an predetermined conductive port (not shown) found elsewhere comprised of substrate 316 that will also aid to circuit portions 6901s' electrical complementary charge switching effect.
- Complementary charge switching effect is due to the attachment configurations of identically configured 400 unit, which can be coupled and energized to share a third common conductive pathway 314/315 to 313 or other area not coupled to 313.
- Solder material 315 is used to couple together in a conductive manner electrode termination portions 802Aand 802B to conductive material pad portion 314 to optional conductive pad/vias 314, 315 to get to earthen ground 313 or similar.
- Pad 314 could also be conductively part of conductive pad/vias 314, 315 which would then lead to conductive area or ground 313, or elsewhere if predetermined, which can in turn, can either "float" in an energized operation like a usage in an un-grounded DC motor as such a DC motor is a portion of an energized automobile electrical system
- an operating circuit 6900 comprising a circuit assembly 6902, where the common shielding electrodes are used as a primary energy return pathway 322, but rather, as a grouping of common shielding electrodes attached to a third conductive pathway conductive pad/vias
- circuit assembly 6900 with grouped third pathway conductive attachments that utilize and one invention 400 in FIG. 2A, 2B and 2C, will illustrate as a predetermined tri-pathway, circuit assembly formed by predetermined conductive material attachments.
- predetermined coupled combination of three predetermined independent groups of electrodes that are electrostatically shielding, two isolated and separate predetermined groups of shielded active electrode circuit pathways from each other while also located on opposite sides of a common ground 313 found between a energy source 301 and an energy utilizing load 307 can be practicable as coupled circuit portions for using a commonly utilized common conductive third external pathway comprising conductive pad/vias 314, 315 to 313, that could be, but is not necessarily a primary energy return pathway 309 in a predetermined closed operating circuit 6900, now created during at least energization, for a low impedance pathway to a common conductive area 313 along third common conductive pathway pad/vias 314, 315
- invention circuit and invention unit 400 should be located as close to the load 307 as possible, this will minimize the stray inductance and resistance associated with the internal electrode portion of circuit traces 301, 322, thereby taking full advantage of the invention circuit and device properties and capabilities for utilization by the portions taking the energy paths in their propagations to undergo conditioning.
- portions of propagating energies found in the operating circuits such as 6900, will operate in a complete by-pass propagation mode with respect to overall handling by respective physically active by-pass external energy pathways coupled to either locations upon embodiment 400 to operate in a by-pass relationship back to the energy-load 307 and partially within the device 400, as these portions of propagating energies return back to the source 301.
- the external energy pathways will stop at the conductive connections found leading into assembly 6900 like shown on FIG. 14A, pass through the active electrode portions and begin externally on each respective external pathway on the opposite side of the invention.
- the external third pathway-coupling scheme will dynamically aid the invention embodiments in providing operable common voltage reference for the shielded electrode pathways but the predetermined external third pathway connection scheme aids the electrostatic shielding function that allows dynamic shielding operability protection to portions of electronic system circuitry.
- a predetermined third energy pathway is normally found to be electrically isolated from, but can be found internally adjacent to, the electrically opposing, complementary, differential electrode energy pathways or power/signal planes.
- a predetermined third energy pathway is also coupled extension of the outer external common conductive pathway, extension. This predetermined third energy pathway can also be utilized in one invention device for certain predetermined circuitries or bus lines as opposed to utilizing many individual discrete low impedance decoupling capacitors positioned in parallel within a comparable circuit system in an attempt to accomplish the same goal.
- these external circuit pathways or traces 303 and 309 to be contiguous in the appearance and the invention would simply be placed coupled, over and on top theses external energy pathways coupled on either side to allow some portions of energy to use the pathways as if the units were not coupled to them, while other portions of energies will enter into the invention units and their respective AOIs of the AOC's.
- the number of conductive pathways can be multiplied in a predetermined manner to create a number of conductive pathway element combinations in a generally physical parallel relationship that also be considered electrically parallel in relationship with respect to these elements in an energized existence with respect to a circuit source will exist additionally in parallel which thereby add to create increased capacitance values.
- some of the various energy conditioning functions obtained with usage of the energized circuit using the third pathway connection scheme include, but are not limited to, simultaneous, certain conditional, filtering, surge protection and energy decoupling, certain conditional mutual flux cancellation of certain types of electromagnetic energy field propagations, containment and suppression of portions of E & H electromagnetic energy field propagation or the various parasitic emissions originating form these fields with minimal portions of energy degradation not normally found by using prior embodiments that do not comprise such elements as described in preceding text.
- a common, shielding electrode that is paired with two additionally positioned common electrode pathways or electrode shields are generally desired and these two additionally positioned common electrode pathways or electrode shields should be divided and positioned on opposite sides of the central common electrode shield with respect to each other and the one central shielding, common electrode.
- 800/800-IM is predetermined to be arranged and positioned, shared and in-between the remaining, other invention elements, the larger common conductive shield structure and finally, the conductive attachment(s) of a common external conductive element(s) that is/are working in combination together, using electrostatic shielding suppression techniques as well as, physical shielding, for influencing and conditioning portions of energy that are propagated within a circuit system that one of the various invention embodiments is incorporated into for usage.
- the additional sandwiching, common -IM shielding pathway electrodes surrounding the combination of a center common shielding electrode pathway with interposing shielding pathway electrodes substantially immuring predetermined pluralities of smaller, shielded electrodes are employed to provide an increased and an optimized, cage-like shielding function and surge dissipation area in all embodiments.
- the circuit assembly is practicable to be operable with grouped internal and external and the third pathway conductive attachments (other than of dielectric material) when energized.
- This new assembly combination reveals unequivocally that a factor causing results and improved circuit performances are predicated upon an invention comprising a predetermined, balanced grouping of elements within the embodiments that are centered around the inventions balanced material portions, the inventions balanced, symmetrical arrangement of the material structure in a mirrored relationship on both sides of the structure totally balanced internal or found on, either side of the centrally positioned, common, shielding electrode 800/800-IM.
- predetermined elements their quantities, composition or their predetermined arranged groupings that are selected for in-combination amalgamation with the invention will substantially determine what type or what kind of portions of various energy conditioning functions an average user could expect to observe or benefit from as a result attributed to a predetermined amalgamated combination with the invention.
- the invention will also minimize or suppress as well as prevent harmful and unwanted energy parasitics originating from either of the paired and oppositely co-acting, differential conductive energy pathways connected to circuitry, respectively, from upsetting one another, portions of the propagating circuit energy or voltage balance within the AOC of the invention.
- the invention will also minimize or suppress as well as prevent harmful and unwanted energy parasitics and provide a subsequent conduction pathway of release for escaping in the form of common mode energies and the like back into the circuit system to detrimentally affect a larger circuitry, outside the AOC influence.
- the shape, thickness or size may be varied depending on the electrical application derived from the arrangement of common, shielding electrode pathways, attachment structures that form at least one single conductively homogenous faraday cage-like structure and other conductive electrode pathways.
- the predetermined physically balanced arrangements and distance relationships that at energization will be simultaneously operable for contributed amalgamated energy conditioning upon various energy portions found utilizing the amalgamated invention elements.
- the contribution of each individual conductive element will create a sum of the whole that is larger than the sum of the parts taken individually.
- the material 801 having predetermined electrical properties may be one of a number in any of the embodiment portions including but not limited to dielectric material, metal oxide varistor material, ferrite material and other more exotic substances such as Mylar film or sintered poly crystalline.
- the combination of larger, shielding, common electrode and electrode creates a plurality of capacitors to form a line-to-line differential coupling capacitor between and two line-to-third energy pathway decoupling capacitors from a pair of electrical conductors.
- the material 801 having electrical properties will vary the capacitance values and/or add additional features such as over-voltage and surge protection or increased inductance, resistance, or a combination of all the above.
- the number of electrodes, both common conductive and electrode can be multiplied to create a number of capacitive elements in parallel which thereby add to create increased capacitance values.
- third, additional same sized, shielding, common electrode surrounding the combination of a center electrode and a plurality of electrodes are employed to provide an increased inherent third energy pathway and optimized electrostatic shielding function and surge dissipation area in all embodiments.
- one central common conductive shield is paired with two adjacent and additionally positioned, smaller, common electrodes or shields are also generally desired and should be positioned as well divided and on opposite sides of the central common conductive shield, additional smaller, shielding, common, shielding electrodes can be employed with any of the embodiment portions shown and is fully contemplated by Applicant.
- the multi-functional energy conditioner although not shown, could easily be fabricated in silicon and directly incorporated into integrated circuits for use in such applications as communication microprocessor integrated circuitry or chips.
- integrated circuits are already being made having capacitors etched within the silicone foundation which allows the architecture of the present invention to readily be incorporated with technology available today.
Abstract
Description
Claims
Priority Applications (7)
Application Number | Priority Date | Filing Date | Title |
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JP2001581305A JP2004509451A (en) | 2000-04-28 | 2001-04-30 | A predetermined symmetrically balanced mixture having a complementary pair of parts with a shielding electrode and a shielded electrode and a symmetrically balanced complementary energy part other predetermined element parts for conditioning; |
AU2001261095A AU2001261095B2 (en) | 2000-04-28 | 2001-04-30 | Predetermined symmetrically balanced amalgam with complementary paired portions comprising shielding electrodes and shielded electrodes and other predetermined element portions for symmetrically balanced and complementary energy portion conditioning |
CA002413222A CA2413222A1 (en) | 2000-04-28 | 2001-04-30 | Predetermined symmetrically balanced amalgam with complementary paired portions comprising shielding electrodes and shielded electrodes and other predetermined element portions for symmetrically balanced and complementary energy portion conditioning |
EP01934954A EP1303898A4 (en) | 2000-04-28 | 2001-04-30 | Predetermined symmetrically balanced amalgam with complementary paired portions comprising shielding electrodes and shielded electrodes and other predetermined element portions for symmetrically balanced and complementary energy portion conditioning |
AU6109501A AU6109501A (en) | 2000-04-28 | 2001-04-30 | Predetermined symmetrically balanced amalgam with complementary paired portions comprising shielding electrodes and shielded electrodes and other predetermined element portions for symmetrically balanced and complementary energy portion conditioning |
IL15248801A IL152488A0 (en) | 2000-04-28 | 2001-04-30 | Predetermined symmetrically balanced amalgam with complementary paired portions comprising shielding electrodes and shielded electrodes and other predetermined element portions for symmetrically balanced and complementary energy portion conditioning |
IL152488A IL152488A (en) | 2000-04-28 | 2002-10-27 | Predetermined symmetrically |
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CN1890854A (en) * | 2003-12-22 | 2007-01-03 | X2Y艾泰钮埃特有限责任公司 | Internally shielded energy conditioner |
GB2439861A (en) | 2005-03-01 | 2008-01-09 | X2Y Attenuators Llc | Internally overlapped conditioners |
CN110044253A (en) * | 2019-05-27 | 2019-07-23 | 中国工程物理研究院电子工程研究所 | A kind of micro motor and embedded angle measurement unit |
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US5668511A (en) * | 1994-03-29 | 1997-09-16 | Murata Manufacturing Co., Ltd. | Low-pass filter |
US5834992A (en) * | 1995-12-28 | 1998-11-10 | Murata Manufacturing Co., Ltd. | LC resonant part with a via hole inductor directly connected to the ground electrode |
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JPS6016411A (en) * | 1983-07-08 | 1985-01-28 | 株式会社村田製作所 | Laminated porcelain condenser |
JPS60254608A (en) * | 1984-05-30 | 1985-12-16 | 株式会社村田製作所 | Laminated ceramic condenser |
JPH0440265Y2 (en) * | 1985-07-15 | 1992-09-21 | ||
JPS62199927A (en) * | 1986-02-28 | 1987-09-03 | Taiho Kogyo Co Ltd | Control method for supercharger associated with wet clutch |
JPH02251120A (en) * | 1989-03-24 | 1990-10-08 | Murata Mfg Co Ltd | Laminated capacitor |
JPH06349666A (en) * | 1993-06-02 | 1994-12-22 | Taiyo Yuden Co Ltd | Multilayered ceramic capacitor |
JPH07263269A (en) * | 1994-03-22 | 1995-10-13 | Tdk Corp | Laminated ceramic capacitor |
JPH09266130A (en) * | 1996-03-27 | 1997-10-07 | Taiyo Yuden Co Ltd | Multilayer capacitor |
JPH10241991A (en) * | 1997-02-24 | 1998-09-11 | Taiyo Yuden Co Ltd | Laminated capacitor and its trimming method |
JPH10270282A (en) * | 1997-03-21 | 1998-10-09 | Taiyo Yuden Co Ltd | Multilayer ceramic capacitor |
JPH11204372A (en) * | 1997-11-14 | 1999-07-30 | Murata Mfg Co Ltd | Monolithic capacitor |
CN1293831A (en) * | 1998-01-19 | 2001-05-02 | X2Y衰减器有限公司 | Paired multi-layered dielectric independent passive component architecture resulting in differential and common mode filtering with surge protection in one integrated package |
-
2001
- 2001-04-30 KR KR1020027014536A patent/KR100541828B1/en not_active IP Right Cessation
- 2001-04-30 EP EP01934954A patent/EP1303898A4/en not_active Withdrawn
- 2001-04-30 JP JP2001581305A patent/JP2004509451A/en active Pending
- 2001-04-30 IL IL15248801A patent/IL152488A0/en active IP Right Grant
- 2001-04-30 AU AU6109501A patent/AU6109501A/en active Pending
- 2001-04-30 WO PCT/US2001/013911 patent/WO2001084581A2/en active IP Right Grant
- 2001-04-30 CA CA002413222A patent/CA2413222A1/en not_active Abandoned
- 2001-04-30 AU AU2001261095A patent/AU2001261095B2/en not_active Ceased
- 2001-04-30 CN CNB018220606A patent/CN100367618C/en not_active Expired - Fee Related
Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US5668511A (en) * | 1994-03-29 | 1997-09-16 | Murata Manufacturing Co., Ltd. | Low-pass filter |
US5834992A (en) * | 1995-12-28 | 1998-11-10 | Murata Manufacturing Co., Ltd. | LC resonant part with a via hole inductor directly connected to the ground electrode |
Non-Patent Citations (1)
Title |
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See also references of EP1303898A2 * |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US9054094B2 (en) | 1997-04-08 | 2015-06-09 | X2Y Attenuators, Llc | Energy conditioning circuit arrangement for integrated circuit |
US7356050B2 (en) | 2003-12-17 | 2008-04-08 | Siemens Aktiengesellschaft | System for transmission of data on a bus |
Also Published As
Publication number | Publication date |
---|---|
AU2001261095B2 (en) | 2004-08-19 |
WO2001084581B1 (en) | 2002-08-01 |
EP1303898A4 (en) | 2009-06-03 |
CN100367618C (en) | 2008-02-06 |
IL152488A0 (en) | 2003-05-29 |
KR100541828B1 (en) | 2006-01-10 |
CN1502157A (en) | 2004-06-02 |
AU6109501A (en) | 2001-11-12 |
KR20030085464A (en) | 2003-11-05 |
EP1303898A2 (en) | 2003-04-23 |
WO2001084581A3 (en) | 2002-06-27 |
CA2413222A1 (en) | 2001-11-08 |
JP2004509451A (en) | 2004-03-25 |
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