WO2001009871A1 - Active matrix array devices with reduced non uniformities across multiplexed electrode groups - Google Patents

Active matrix array devices with reduced non uniformities across multiplexed electrode groups Download PDF

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Publication number
WO2001009871A1
WO2001009871A1 PCT/EP2000/006982 EP0006982W WO0109871A1 WO 2001009871 A1 WO2001009871 A1 WO 2001009871A1 EP 0006982 W EP0006982 W EP 0006982W WO 0109871 A1 WO0109871 A1 WO 0109871A1
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WO
WIPO (PCT)
Prior art keywords
circuit
active matrix
conductors
signal processing
substrate
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Application number
PCT/EP2000/006982
Other languages
French (fr)
Inventor
Martin J. Edwards
Original Assignee
Koninklijke Philips Electronics N.V.
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Filing date
Publication date
Application filed by Koninklijke Philips Electronics N.V. filed Critical Koninklijke Philips Electronics N.V.
Priority to EP00954549A priority Critical patent/EP1116209A1/en
Priority to JP2001514411A priority patent/JP2003506730A/en
Publication of WO2001009871A1 publication Critical patent/WO2001009871A1/en

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Classifications

    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G3/00Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes
    • G09G3/20Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters
    • G09G3/34Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source
    • G09G3/36Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source using liquid crystals
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G3/00Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes
    • G09G3/20Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters
    • G09G3/34Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source
    • G09G3/36Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source using liquid crystals
    • G09G3/3611Control of matrices with row and column drivers
    • G09G3/3685Details of drivers for data electrodes
    • G09G3/3688Details of drivers for data electrodes suitable for active matrices only
    • GPHYSICS
    • G11INFORMATION STORAGE
    • G11CSTATIC STORES
    • G11C7/00Arrangements for writing information into, or reading information out from, a digital store
    • G11C7/10Input/output [I/O] data interface arrangements, e.g. I/O data control circuits, I/O data buffers
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G2300/00Aspects of the constitution of display devices
    • G09G2300/04Structural and physical details of display devices
    • G09G2300/0404Matrix technologies
    • G09G2300/0408Integration of the drivers onto the display substrate
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G2310/00Command of the display device
    • G09G2310/02Addressing, scanning or driving the display screen or processing steps related thereto
    • G09G2310/0264Details of driving circuits
    • G09G2310/027Details of drivers for data electrodes, the drivers handling digital grey scale data, e.g. use of D/A converters
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G2310/00Command of the display device
    • G09G2310/02Addressing, scanning or driving the display screen or processing steps related thereto
    • G09G2310/0264Details of driving circuits
    • G09G2310/0297Special arrangements with multiplexing or demultiplexing of display data in the drivers for data electrodes, in a pre-processing circuitry delivering display data to said drivers or in the matrix panel, e.g. multiplexing plural data signals to one D/A converter or demultiplexing the D/A converter output to multiple columns
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G2320/00Control of display operating conditions
    • G09G2320/02Improving the quality of display appearance
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G3/00Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes
    • G09G3/20Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters
    • G09G3/2007Display of intermediate tones
    • G09G3/2011Display of intermediate tones by amplitude modulation

Definitions

  • the present invention relates to an active matrix array device comprising an array of individually addressable matrix elements, first and second sets of crossing address conductors connected to the matrix elements, the array of matrix elements and the sets of address conductors being carried on a substrate, and an addressing circuit connected to the sets of row and column conductors for addressing the matrix elements and comprising a multiplexing circuit integrated on the substrate which is connected to the first set of conductors and has a plurality, n, of signal bus lines, the address conductors of the first set being arranged in a series of groups with each group comprising n successive address conductors and the multiplexing circuit being arranged to couple sequentially each group of address conductors to the signal bus lines with each address conductor in a group being coupled to a respective one of the bus lines, the addressing circuit further including a respective signal processing circuit connected to each bus line.
  • the matrix array device may, for example, be an active matrix liquid crystal (LC) display device.
  • LC liquid crystal
  • Such a device typically comprises an array of liquid crystal display elements each of which is connected to the output of a respective TFT (thin film transistor) to which gating (selection) and data (video information) signals are supplied by respective row and column conductors.
  • TFT thin film transistor
  • the addressing circuit consists of a row drive circuit connected to the row conductors for applying a gating signal to each row conductor in sequence to turn on the TFTs of each row of display elements in turn in respective row address periods and a column drive circuit connected to the set of column conductors for applying data signals to the column conductors in synchronism with scanning of the row conductors whereby the display elements of a selected row are charged via their respective TFTs to a level dependent on the value of the data signal existing on their associated column conductors to produce a required display effect.
  • the TFTs usually comprise either amorphous silicon (a-Si) TFTs or polysilicon TFTs.
  • parts of the row and/or column drive circuits can be integrated on the substrate carrying the TFTs of the display elements peripherally of the display element array using the same large area electronics technology as that employed for the active matrix circuitry of the array with the circuitry of the drive circuit being fabricated simultaneously and similarly comprising TFTs, conductor lines , etc.
  • the column drive circuit is customarily provided in the form of a simple multiplexing circuit, examples of which are described in US-A-4890101 , and the paper entitled "Fully Integrated Poly-Si TFT CMOS Drivers for Self-Scanned Light Valve" by Y.
  • the operation of the column drive circuit is based on a multiplexing technique in which the video information (data) is sequentially transferred via multiplexing switches from a plurality of video input bus lines, to which video information is applied simultaneously, to corresponding groups or blocks of column conductors in the display with each column conductor in a group being connected via a multiplexer switch to a different video input line.
  • this circuit is of an analogue multiplexing type comprising groups of multiplexing switches, in the form of TFTs or CMOS gates, a set of video signal bus lines and a control circuit (normally comprising a shift register) which controls the operation of the multiplexer switches.
  • Groups of video samples, constituting data, taken from an input video signal are applied to the video bus lines and the data is then transferred to corresponding groups of column conductors in the display array during a video line period, which corresponds to a row address period.
  • the video information applied to the video bus lines is generated using external signal processing circuits (i.e. separate to the integrated multiplexing circuit), one such circuit being provided for each respective bus line, and which may consist of sample and hold circuits or digital to analogue (D/A) converters.
  • external signal processing circuits i.e. separate to the integrated multiplexing circuit
  • D/A digital to analogue
  • circuit components of the address circuitry could be integrated on the device substrate in similar manner to the multiplexing circuit for example using TFTs etc formed by the same thin film technology employed for the active matrix array.
  • the circuit components could then be fabricated simultaneously with the active matrix array thereby simplifying manufacture and reducing cost.
  • Such integration would also lead to a more compact arrangement and reduce the number of external connections required.
  • an active matrix array device of the kind described in the opening paragraph which is characterised in that the signal processing circuits associated with the bus lines are integrated as respective circuit blocks on the device substrate with the individual signal processing circuit blocks associated with adjacent column conductors being located close together on the device substrate.
  • the active matrix array of the invention thus includes additional addressing circuitry components, i.e. the signal processing circuits, which are integrated, together with the multiplexing circuit, on the substrate of the device.
  • the invention also entails arranging the column conductor addressing circuitry in a certain manner. As a result, potential operational problems which could be caused by the nature of this integrated circuitry are avoided or at least reduced.
  • the invention stems in part from a recognition that operational problems can result due to deficiencies in the behavioural characteristics of circuit elements when using thin film circuit components, such as TFTs and capacitors, and thin film conductor interconnections for such purposes.
  • thin film circuit components such as TFTs and capacitors
  • thin film conductor interconnections for such purposes.
  • the operational characteristics of individual thin film elements such as TFTs will normally be similar where the elements are formed physically close together but can vary significantly in the case of elements formed further apart due, for example, to slight variations over the area of the device in the thicknesses of individual deposited layers.
  • the n signal processing circuits associated with the n signal bus lines were arranged simply juxtaposed in a line in and ordered in a manner corresponding to the order of the bus lines, and column conductors with which they are respectively associated with successive bus lines supplying successive column conductors, i.e. with the first, second, third etc circuits connected to respectively the first, second, third etc bus lines, and thus the first, second, third etc column conductors in a group, the operational characteristics of the signal processing circuits associated with the first and last column conductors in a group can vary significantly.
  • the variation in output voltage provided by the first and last converters to their respective bus lines, associated with the first and last column conductors in a group will likely be the greatest due to them being the furthest apart on the substrate.
  • the last column conductor in one group is adjacent the first column conductor in the succeeding group, then the output voltage signals generated by the first and last converters will appear on adjacent column conductors at regular intervals over the array and differences in the voltages applied to each adjacent pair will produce display non- uniformities in the nature of periodic, highly visible, steps in brightness across the display.
  • the order in which the signal processing circuit blocks are arranged physically on the device substrate is different to the physical order of the signal bus lines to which they are respectively connected.
  • the invention is particularly attractive for use in active matrix display devices, and especially AMLCDs, the technique can be applied to similar advantage in other kinds of active matrix array devices.
  • active matrix sensing array devices such as image sensing devices as described in EP-A-0569090 (PHB 33792) and fingerprint sensing devices as described in US-A-5325442 (PHB 33628) and the like.
  • PHB 33792 image sensing devices as described in EP-A-0569090
  • PHB 336248 fingerprint sensing devices as described in US-A-5325442
  • These devices similarly comprise an array of elements addressed via sets of row and column conductors.
  • the elements comprise light sensing or capacitive sensing elements and in operation each element provides an output signal, in the form of an electrical charge, along an associated address conductor of one set to which a sense amplifier is connected.
  • the conductors of the one set are preferably connected via a multiplexing circuit to a set of sense amplifiers.
  • the multiplexing circuit and the sense amplifier circuits constituting the aforementioned signal processing circuits, can be integrated on the same substrate as the sensing element array similarly using thin film technology and with the sense amplifiers arranged physically on the substrate so as to reduce the effect of variations in voltages etc in the individual sense amplifier circuits caused by differences in the operational characte ⁇ stics of thin film elements in these circuits when spaced widely apart on the substrate.
  • Figure 1 is a simplified schematic circuit diagram of an embodiment of active matrix LC display device according to the invention.
  • Figure 2 illustrates schematically the circuit of a typical example of multiplexer circuit as used in active matrix array devices such as AMLCDs and the like;
  • Figure 3 illustrates diagrammatically a possible lay-out of drive circuit components in an AMLCD
  • FIGS. 4 and 5 illustrate diagrammatically alternative lay-out arrangements for drive circuit components in accordance with the present invention. It will be appreciated that the figures are merely schematic and have not been drawn to scale. The same reference numbers are used throughout the figures to indicate the same or similar parts.
  • the active matrix LC display device comprises a row and column array of individually operable liquid crystal display elements 10.
  • the display elements each have an associated TFT 12 acting as a switching device and are addressed by peripheral addressing circuitry via sets of row and column address conductors 14 and 16 and comprising a row drive circuit 30 and a column drive circuit 35 connected respectively to the sets of row and column conductors. Only a few typical display elements are shown for simplicity but in practice there would normally be at least several hundred rows and columns of such elements.
  • the drain of a TFT 12 is connected to a respective display element electrode 18 situated adjacent the intersection of respective row and column address conductors, while the gates of all the TFTs associated with a respective row of display elements 10 are connected to the same row address conductor 14 and the sources of all the TFTs associated with a respective column of display elements are connected to the same column address conductor 16.
  • the sets of row and column address conductors 14, 16, the TFTs 12, and the picture element electrodes 18 are all carried on the same insulating substrate 25, for example of glass, and fabricated in conventional manner using known thin film technology involving the deposition and photolithographic patterning of various conductive, insulating and semiconductive layers.
  • a second glass substrate, (not shown) carrying a continuous transparent electrode common to all display elements in the array is arranged spaced from the substrate 25 and the two substrates are sealed together around the periphery of the display element array and separated by spacers to define an enclosed space in which liquid crystal material is contained.
  • Each display element electrode 18 together with an overlying portion of the common electrode and the liquid crystal material therebetween defines a light-modulating capacitive display element.
  • Scanning (gating) signals are applied to each row address conductor 14 in turn by the row driver circuit 30, comprising for example a digital shift register, and data signals are applied to the column conductors 16, in synchronisation with the gating signals, by the column drive circuit 35.
  • the TFTs 12 connected to that row conductor are turned on causing the respective display elements to be charged according to the level of the data signal then existing on their associated column conductors.
  • the associated TFTs are turned off for the remainder of the field period in order to isolate electrically the display elements and ensure the applied charge is stored on the LC capacitance to maintain their display outputs until they are addressed again in a subsequent field period.
  • the row and column drive circuits 30 and 35 are both integrated on the substrate 25 with their circuitry being formed simultaneously with the fabrication active matrix array using the same thin film technology and similarly comprising TFTs, conductor lines, capacitors, etc.
  • the row drive circuit 30 is of convention form, comprising for example a simple shift register circuit whose operation is controlled by timing signals provided by an external timing and control circuitry (not shown) to which digital video data is supplied from a suitable source.
  • the digital video information (data) signals are supplied by the timing and control circuitry to the column drive circuit 35 which operates to apply to the set of conductors 16 analogue voltage signals derived from this data in parallel for each row of display elements in turn so as to produce the desired display effects from the displays element in each row according to the supplied data.
  • the column drive circuit 35 is of the analogue multiplexing kind and has an integrated multiplexing circuit providing a respective output for each column conductor 16.
  • a typical example of a simple known form of multiplexing circuit, 31 is illustrated, in part, in Figure 2.
  • the general operation of such a circuit is based on a multiplexing technique in which analogue video information is sequentially transferred from a plurality of video input bus lines supplied in parallel with video data to corresponding groups of column address conductors in the display device.
  • the video information is transferred via multiplexing switches, 32, which may consist of NMOS TFTs, PMOS TFTs or CMOS transmission gates.
  • the switches which each constitute an output of the circuit associated with a respective column conductor, are operated in groups and when a group of switches is turned on the corresponding columns are charged according to the data signal voltage levels then existing on the respective associated video bus lines.
  • each group of multiplexing switches is turned on in sequence until all of the columns of display elements have been charged with the appropriate video information.
  • V1 to V9 arranged physically in order corresponding to their number to which input video signals are applied in parallel, and the multiplexing switches, 32, are arranged in groups of nine with their outputs connected to respective and consecutive, ones of the column address conductors 16, C1-9, C10-18, etc.
  • a control circuit 37 comprising a shift register, sequentially selects each of the groups of multiplexing switches by way of the control signals G1 , G2, etc so that at the end of the row address period all the columns in the array have been charged.
  • G1 goes high the first nine multiplexer switches 32 close and the first nine columns C1 to C9 are charged to the voltage level on the video lines V1 - V9 respectively.
  • the analogue video signals required for the video bus lines 33 are supplied from external circuitry, comprising, in the case of digital video signals being used, digital to analogue converter circuits.
  • the digital to analogue converter circuits are also integrated, together with the multiplexing circuit 31 , on the array substrate and comprise thin film circuit elements, i.e. TFTs, conductor lines, capacitors etc fabricated simultaneously with the active matrix array.
  • TFTs thin film circuit elements
  • each D/A converter circuit includes an input latch circuit.
  • the digital to analogue converter circuits are arranged physically on the substrate as a set or series of respective blocks occupying substantially separate areas of the substrate, the number of such blocks corresponding to the number of video bus lines 33, (and column conductors in each group).
  • the order in which these blocks are arranged with respect to each other on the substrate and in relation to the video bus lines which they supply, and hence the order of the column conductors they serve, is such as to avoid potential problems with the quality of the display produced as will now be explained.
  • Figure 3 shows schematically one possible lay-out of the digital to analogue converter circuit blocks in relation to the display element array and the multiplexing circuit.
  • the display element array is denoted generally at 40 and the multiplexing circuit 31 , including the video signal bus lines, extends generally parallel to, and alongside, one edge of the array with the individual outputs of the circuit 31 being connected to respective column conductors 16 in the array.
  • the nine converter circuit blocks are indicated at 42 with the individual numbers (1-9) assigned thereto designating the respective number of the video bus line (V1 - V9) with which they are associated. As shown, these blocks are arranged juxtaposed in a row generally parallel with the multiplexing circuit 31 and its video bus lines and adjacent an edge of the device substrate 25. Power supply, timing signals and video information signals are supplied to the blocks from an external timing and control circuit, here shown at 45, which also supplies power and timing signals to the multiplexing circuit 31.
  • the blocks are ordered numerically and their respective outputs 44, along which the video signals V1 to V9 are supplied, are connected to the appropriate bus lines 33 in the multiplexing circuit 31 at regularly - spaced locations, corresponding to the block spacings, rather than to the ends of these lines.
  • the individual circuit blocks 42 generally occupy discrete and respective regions of the substrate surface, although of course certain components such as clock and power lines will be shared between blocks.
  • successive ones of the series of digital to analogue circuit blocks supply respectively successively - numbered video bus lines 33, and hence successive column conductors in the groups, i.e. C1 to C9, C10 to C18, etc.
  • Such an arrangement has been found to lead to problems with the display quality.
  • the cause of this has been identified as slight variations in the operation, and especially voltages generated in, different ones of the converter circuits due principally to the nature of the fabrication of the thin film elements constituting these circuits.
  • a resultant variation in output voltage as supplied to the column conductors will tend to be greatest between converter circuit 1 and the converter circuit 9 in this example as these two converter circuits are spaced physically on the substrate 25 the furthest apart.
  • These voltage variations can arise for a number of reasons but in general are due to variations in the operational characteristics of individual TFTs or dielectric layer thicknesses over the substrate, or from voltage losses along thin film signal lines feeding the converter circuits.
  • the consequential variation of voltages tend to be the most significant with circuit blocks widely separated on the substrate, the variation in voltages produced in blocks physically closer together, and therefore whose thin film circuit elements are much less widely separated, will likely be minimal.
  • the lay-out of the converter circuits on the substrate is modified such that converter circuits which are to supply adjacent columns in the array are placed close together. The effect of this is to reduce the change in voltage which occurs moving from one column to the next, although the maximum voltage difference which can occur for columns in any one complete multiplexer group will be unchanged.
  • Figure 4 illustrates, for comparison with Figure 3, the lay-out of the column drive circuit components in one embodiment according to the present invention. From this figure, it is seen that the nine converter circuit blocks 1 to 9 are again arranged in series in a line parallel to the multiplexing circuit 30 but that the blocks 42 are arranged in a different, and particular, numerical order. Thus, the converter circuit blocks 1 and 9 are arranged physically immediately adjacent one another. The other blocks 2 to 8 are similarly arranged physically on the substrate 25 to reduce the effects of voltage variations. Hence, block 2 is arranged between blocks 9 and 8, rather than being widely separated from these blocks as in the Figure 3 arrangement, and so on. The complete sequence of the blocks, as shown in Figure 4, is 1 , 9, 2, 8, 3, 7, 4, 6 and 5, and it will be apparent that no two adjacent columns are therefore supplied with voltages from widely separated blocks.
  • Figure 5 illustrates schematically another possible arrangement of the column drive circuit components in accordance with the invention.
  • This embodiment differs from the previous embodiment in that the converter circuit blocks 42 are laid out instead in two rows and with the blocks in one row being offset from those in the other in brick-like fashion but with the numerical order of the overlapping blocks in the direction of the rows being the same as before.
  • the circuits blocks associated with some pairs of adjacent column conductors lie even closer together. The arrangement allows each block to occupy more space in the row direction, although a greater overall space in the column direction is required to accommodate the two rows of blocks.
  • the column drive circuit may be of a type to which analogue video information is applied instead, in which case each of the circuit blocks 42 can comprise a sample and hold circuit with buffer amplifier, or other known form of analogue video signal processing circuit suitable for the required purpose.
  • the converter circuit blocks have been shown as arranged parallel to the multiplexing circuit between an edge of the display element array and an edge of the substrate 25, the same principles can be applied in the case where the circuits are located elsewhere on the substrate, for example closer to region where the externally provided video signal is supplied to the substrate.
  • the blocks 42 could be arranged other than linearly in one or more rows. If the region of the substrate available to accommodate the circuit blocks allows, the blocks could be arranged in a square pattern or even in a curved line.
  • the column drive circuit 35 for the array comprises a single unit.
  • the column drive circuit may effectively be split into two separate (sub-) circuits, each of which would be similar to the previously described drive circuit 35 but addressing just one half of the set of column conductors, and with the two circuits operating simultaneously in parallel and generally independently, although controlled appropriately by the timing and control unit 45.
  • each with its separate set of video bus lines faster operation becomes possible and problems due to the lengths of the video bus lines and their resistance are reduced since their individual lengths are now much shorter, for example corresponding approximately to half the row length.
  • the video signal bus lines V1 to V9 can supply red, green, blue, red, green, blue, etc. colour information, in which case the blocks 42 in the Figure 4 example would, starting at the left, operate with red, blue, green, green, blue, red, etc colour information respectively.
  • the active matrix display device may be of a type using display elements other than LC display elements for example, electroluminescent or electro-chromic display elements.
  • the invention is applicable also to other kinds of active matrix array devices in which it would be desirable to integrate more of the addressing circuitry, such as sensor array devices in which matrix sensing elements comprise, for example, optical sensing elements as in image sensing array devices, or pressure or capacitive sensing elements as in touch or fingerprint sensing array devices, and in which the matrix array of sensing elements are similarly addressed via sets of row and column conductors.
  • sensor array devices in which matrix sensing elements comprise, for example, optical sensing elements as in image sensing array devices, or pressure or capacitive sensing elements as in touch or fingerprint sensing array devices, and in which the matrix array of sensing elements are similarly addressed via sets of row and column conductors.
  • image sensing device and fingerprint sensing device are described in EP-A-0569090 and US-A-5325 442 respectively.
  • each row of the matrix elements is selected via an associated address conductor of one set and data from the elements of the selected row, usually in the form of electrical charges, is read out via respective conductors of the other set.
  • the conductors of this other set can be coupled to a multiplexing circuit similar to that of Figure 2 and with the bus lines connected to respective associated sense amplifiers responsive to the element outputs.
  • the sense amplifiers can be integrated, together with the multiplexing circuit, on the same substrate as the array of sense elements, and fabricated, using thin film technology, simultaneously with the sense element array, and with the individual sense amplifier circuit blocks being laid-out in the manner described to avoid problems caused by variation in the operational characteristics of the sense amplifier circuits which are situated further apart.

Abstract

An active matrix array device, such as an AMLCD, has an array of matrix elements (10) addressed via sets of address conductors (14, 16). An address circuit (35) connected to one set (16) comprises a multiplexing circuit (31) integrated on the same substrate (25) as the matrix elements which has a plurality of signal bus lines (33), the one set of address conductors being organised in groups with each conductor in a group being associated with a respective and different signal bus line and the groups being addressed in sequence. Each signal bus line is connected to a respective signal processing circuit (42), e.g. a D/A converter or sample and hold circuit in the case of an AMLCD, which is also integrated on the substrate. To avoid problems in use due to the manner of fabrication of these circuits and the operation of the multiplexing circuit, the address circuit is arranged so that the individual signal processing circuits associated with adjacent column conductors are located close together on the substrate.

Description

ACTIVE MATRIX ARRAY DEVICES WITH REDUCED NON UNIFORMITIES ACROSS MULTIPLEXED ELECTRODE GROUPS
The present invention relates to an active matrix array device comprising an array of individually addressable matrix elements, first and second sets of crossing address conductors connected to the matrix elements, the array of matrix elements and the sets of address conductors being carried on a substrate, and an addressing circuit connected to the sets of row and column conductors for addressing the matrix elements and comprising a multiplexing circuit integrated on the substrate which is connected to the first set of conductors and has a plurality, n, of signal bus lines, the address conductors of the first set being arranged in a series of groups with each group comprising n successive address conductors and the multiplexing circuit being arranged to couple sequentially each group of address conductors to the signal bus lines with each address conductor in a group being coupled to a respective one of the bus lines, the addressing circuit further including a respective signal processing circuit connected to each bus line.
The matrix array device may, for example, be an active matrix liquid crystal (LC) display device. Such a device typically comprises an array of liquid crystal display elements each of which is connected to the output of a respective TFT (thin film transistor) to which gating (selection) and data (video information) signals are supplied by respective row and column conductors. The addressing circuit consists of a row drive circuit connected to the row conductors for applying a gating signal to each row conductor in sequence to turn on the TFTs of each row of display elements in turn in respective row address periods and a column drive circuit connected to the set of column conductors for applying data signals to the column conductors in synchronism with scanning of the row conductors whereby the display elements of a selected row are charged via their respective TFTs to a level dependent on the value of the data signal existing on their associated column conductors to produce a required display effect. The TFTs usually comprise either amorphous silicon (a-Si) TFTs or polysilicon TFTs.
For convenience of manufacture and compactness, parts of the row and/or column drive circuits can be integrated on the substrate carrying the TFTs of the display elements peripherally of the display element array using the same large area electronics technology as that employed for the active matrix circuitry of the array with the circuitry of the drive circuit being fabricated simultaneously and similarly comprising TFTs, conductor lines , etc. Due to limitations in operational performance of the TFTs and the kinds of circuit possible when using TFTs, the column drive circuit is customarily provided in the form of a simple multiplexing circuit, examples of which are described in US-A-4890101 , and the paper entitled "Fully Integrated Poly-Si TFT CMOS Drivers for Self-Scanned Light Valve" by Y. Nishihara et al in SID 92 Digest, pages 609 - 612. The operation of the column drive circuit is based on a multiplexing technique in which the video information (data) is sequentially transferred via multiplexing switches from a plurality of video input bus lines, to which video information is applied simultaneously, to corresponding groups or blocks of column conductors in the display with each column conductor in a group being connected via a multiplexer switch to a different video input line. Commonly in polysilicon TFT display devices having an integrated column drive circuit this circuit is of an analogue multiplexing type comprising groups of multiplexing switches, in the form of TFTs or CMOS gates, a set of video signal bus lines and a control circuit (normally comprising a shift register) which controls the operation of the multiplexer switches. Groups of video samples, constituting data, taken from an input video signal are applied to the video bus lines and the data is then transferred to corresponding groups of column conductors in the display array during a video line period, which corresponds to a row address period.
In known kinds of these display devices, the video information applied to the video bus lines is generated using external signal processing circuits (i.e. separate to the integrated multiplexing circuit), one such circuit being provided for each respective bus line, and which may consist of sample and hold circuits or digital to analogue (D/A) converters.
It would be advantageous for additional circuit components of the address circuitry to be integrated on the device substrate in similar manner to the multiplexing circuit for example using TFTs etc formed by the same thin film technology employed for the active matrix array. The circuit components could then be fabricated simultaneously with the active matrix array thereby simplifying manufacture and reducing cost. Such integration would also lead to a more compact arrangement and reduce the number of external connections required.
It is one object of the present invention to provide an active matrix array device with improvement in this respect.
According to the present invention, there is provided an active matrix array device of the kind described in the opening paragraph which is characterised in that the signal processing circuits associated with the bus lines are integrated as respective circuit blocks on the device substrate with the individual signal processing circuit blocks associated with adjacent column conductors being located close together on the device substrate. The active matrix array of the invention thus includes additional addressing circuitry components, i.e. the signal processing circuits, which are integrated, together with the multiplexing circuit, on the substrate of the device. The invention also entails arranging the column conductor addressing circuitry in a certain manner. As a result, potential operational problems which could be caused by the nature of this integrated circuitry are avoided or at least reduced. In this respect, the invention stems in part from a recognition that operational problems can result due to deficiencies in the behavioural characteristics of circuit elements when using thin film circuit components, such as TFTs and capacitors, and thin film conductor interconnections for such purposes. In large area, thin film technology devices, the operational characteristics of individual thin film elements such as TFTs will normally be similar where the elements are formed physically close together but can vary significantly in the case of elements formed further apart due, for example, to slight variations over the area of the device in the thicknesses of individual deposited layers. If, therefore, the n signal processing circuits associated with the n signal bus lines were arranged simply juxtaposed in a line in and ordered in a manner corresponding to the order of the bus lines, and column conductors with which they are respectively associated with successive bus lines supplying successive column conductors, i.e. with the first, second, third etc circuits connected to respectively the first, second, third etc bus lines, and thus the first, second, third etc column conductors in a group, the operational characteristics of the signal processing circuits associated with the first and last column conductors in a group can vary significantly. Thus in the case for example of the device comprising an active matrix LC display device, with the signal processing circuits comprising, for example, D/A converter circuits, then the variation in output voltage provided by the first and last converters to their respective bus lines, associated with the first and last column conductors in a group, will likely be the greatest due to them being the furthest apart on the substrate. Bearing in mind that the last column conductor in one group is adjacent the first column conductor in the succeeding group, then the output voltage signals generated by the first and last converters will appear on adjacent column conductors at regular intervals over the array and differences in the voltages applied to each adjacent pair will produce display non- uniformities in the nature of periodic, highly visible, steps in brightness across the display. By arranging the circuitry according to the invention, therefore, the visibility of the effect of converter circuit output variations is significantly reduced.
Preferably, the order in which the signal processing circuit blocks are arranged physically on the device substrate is different to the physical order of the signal bus lines to which they are respectively connected.
While the invention is particularly attractive for use in active matrix display devices, and especially AMLCDs, the technique can be applied to similar advantage in other kinds of active matrix array devices. For example, it is envisaged that the invention can be used in active matrix sensing array devices such as image sensing devices as described in EP-A-0569090 (PHB 33792) and fingerprint sensing devices as described in US-A-5325442 (PHB 33628) and the like. These devices similarly comprise an array of elements addressed via sets of row and column conductors. The elements comprise light sensing or capacitive sensing elements and in operation each element provides an output signal, in the form of an electrical charge, along an associated address conductor of one set to which a sense amplifier is connected. The conductors of the one set are preferably connected via a multiplexing circuit to a set of sense amplifiers. In accordance with the present invention, therefore, the multiplexing circuit and the sense amplifier circuits, constituting the aforementioned signal processing circuits, can be integrated on the same substrate as the sensing element array similarly using thin film technology and with the sense amplifiers arranged physically on the substrate so as to reduce the effect of variations in voltages etc in the individual sense amplifier circuits caused by differences in the operational characteπstics of thin film elements in these circuits when spaced widely apart on the substrate.
Embodiments of active matrix array devices in accordance with the invention will now be described, by way of example, with reference to the accompanying drawings, in which:-
Figure 1 is a simplified schematic circuit diagram of an embodiment of active matrix LC display device according to the invention;
Figure 2 illustrates schematically the circuit of a typical example of multiplexer circuit as used in active matrix array devices such as AMLCDs and the like;
Figure 3 illustrates diagrammatically a possible lay-out of drive circuit components in an AMLCD; and
Figures 4 and 5 illustrate diagrammatically alternative lay-out arrangements for drive circuit components in accordance with the present invention. It will be appreciated that the figures are merely schematic and have not been drawn to scale. The same reference numbers are used throughout the figures to indicate the same or similar parts.
Referring to Figure 1 , the active matrix LC display device (AMLCD) comprises a row and column array of individually operable liquid crystal display elements 10. The display elements each have an associated TFT 12 acting as a switching device and are addressed by peripheral addressing circuitry via sets of row and column address conductors 14 and 16 and comprising a row drive circuit 30 and a column drive circuit 35 connected respectively to the sets of row and column conductors. Only a few typical display elements are shown for simplicity but in practice there would normally be at least several hundred rows and columns of such elements. The drain of a TFT 12 is connected to a respective display element electrode 18 situated adjacent the intersection of respective row and column address conductors, while the gates of all the TFTs associated with a respective row of display elements 10 are connected to the same row address conductor 14 and the sources of all the TFTs associated with a respective column of display elements are connected to the same column address conductor 16. The sets of row and column address conductors 14, 16, the TFTs 12, and the picture element electrodes 18 are all carried on the same insulating substrate 25, for example of glass, and fabricated in conventional manner using known thin film technology involving the deposition and photolithographic patterning of various conductive, insulating and semiconductive layers. A second glass substrate, (not shown) carrying a continuous transparent electrode common to all display elements in the array is arranged spaced from the substrate 25 and the two substrates are sealed together around the periphery of the display element array and separated by spacers to define an enclosed space in which liquid crystal material is contained. Each display element electrode 18 together with an overlying portion of the common electrode and the liquid crystal material therebetween defines a light-modulating capacitive display element. Both the general structure and operation of this device follow conventional practice. Scanning (gating) signals are applied to each row address conductor 14 in turn by the row driver circuit 30, comprising for example a digital shift register, and data signals are applied to the column conductors 16, in synchronisation with the gating signals, by the column drive circuit 35. Upon each row conductor being supplied with a gating signal, the TFTs 12 connected to that row conductor are turned on causing the respective display elements to be charged according to the level of the data signal then existing on their associated column conductors. Upon termination of the gating signal at the end of the respective row address period, corresponding for example to the line period of an applied video signal, the associated TFTs are turned off for the remainder of the field period in order to isolate electrically the display elements and ensure the applied charge is stored on the LC capacitance to maintain their display outputs until they are addressed again in a subsequent field period.
The row and column drive circuits 30 and 35 are both integrated on the substrate 25 with their circuitry being formed simultaneously with the fabrication active matrix array using the same thin film technology and similarly comprising TFTs, conductor lines, capacitors, etc. The row drive circuit 30 is of convention form, comprising for example a simple shift register circuit whose operation is controlled by timing signals provided by an external timing and control circuitry (not shown) to which digital video data is supplied from a suitable source.
The digital video information (data) signals are supplied by the timing and control circuitry to the column drive circuit 35 which operates to apply to the set of conductors 16 analogue voltage signals derived from this data in parallel for each row of display elements in turn so as to produce the desired display effects from the displays element in each row according to the supplied data. As is common in AMLCDs having partly integrated column drive circuitry, particularly devices employing polysilicon TFTs, the column drive circuit 35 is of the analogue multiplexing kind and has an integrated multiplexing circuit providing a respective output for each column conductor 16. A typical example of a simple known form of multiplexing circuit, 31 , is illustrated, in part, in Figure 2.
The general operation of such a circuit is based on a multiplexing technique in which analogue video information is sequentially transferred from a plurality of video input bus lines supplied in parallel with video data to corresponding groups of column address conductors in the display device. The video information is transferred via multiplexing switches, 32, which may consist of NMOS TFTs, PMOS TFTs or CMOS transmission gates. The switches, which each constitute an output of the circuit associated with a respective column conductor, are operated in groups and when a group of switches is turned on the corresponding columns are charged according to the data signal voltage levels then existing on the respective associated video bus lines. When the switches turn off the voltages on the column conductors are stored on the capacitance of the column conductors and any additional storage capacitors which may be connected in parallel with them. During a respective video line, row address, period each group of multiplexing switches is turned on in sequence until all of the columns of display elements have been charged with the appropriate video information. In the example of Figure 2, there are nine parallel video input bus lines
33, V1 to V9, arranged physically in order corresponding to their number to which input video signals are applied in parallel, and the multiplexing switches, 32, are arranged in groups of nine with their outputs connected to respective and consecutive, ones of the column address conductors 16, C1-9, C10-18, etc. A control circuit 37, comprising a shift register, sequentially selects each of the groups of multiplexing switches by way of the control signals G1 , G2, etc so that at the end of the row address period all the columns in the array have been charged. When G1 goes high the first nine multiplexer switches 32 close and the first nine columns C1 to C9 are charged to the voltage level on the video lines V1 - V9 respectively. G1 then goes low, opening the nine associated multiplexer switches to isolate the columns C1 to C9 from the video lines. The voltages on the columns are then stored on the column capacitances. Next, the control signal G2 goes high, closing the next group of switches 32 and the second group of nine columns, C10 to C18, is charged to the voltages then existing on the respective video lines 33. The operation of the multiplexing circuit continues in this way with each group of columns being charged appropriately in succession until all the column conductors in the array have been charged in a respective row address period. Subsequent rows of display elements are addressed in similar manner in respective row address periods.
It is usual for the analogue video signals required for the video bus lines 33 to be supplied from external circuitry, comprising, in the case of digital video signals being used, digital to analogue converter circuits. However, and in accordance with one feature of the invention, the digital to analogue converter circuits are also integrated, together with the multiplexing circuit 31 , on the array substrate and comprise thin film circuit elements, i.e. TFTs, conductor lines, capacitors etc fabricated simultaneously with the active matrix array. An example of a digital to analogue converter circuit suitable for this purpose is described in W099/27653 (PHB 34210) although other known D/A converter circuits, such as switched capacitor type circuits, may be suitable as well. As is usual with such circuits, each D/A converter circuit includes an input latch circuit. The digital to analogue converter circuits are arranged physically on the substrate as a set or series of respective blocks occupying substantially separate areas of the substrate, the number of such blocks corresponding to the number of video bus lines 33, (and column conductors in each group).
According to another feature of the invention, the order in which these blocks are arranged with respect to each other on the substrate and in relation to the video bus lines which they supply, and hence the order of the column conductors they serve, is such as to avoid potential problems with the quality of the display produced as will now be explained. For this purpose, reference is made to Figure 3 which shows schematically one possible lay-out of the digital to analogue converter circuit blocks in relation to the display element array and the multiplexing circuit. In Figure 3, the display element array is denoted generally at 40 and the multiplexing circuit 31 , including the video signal bus lines, extends generally parallel to, and alongside, one edge of the array with the individual outputs of the circuit 31 being connected to respective column conductors 16 in the array. The nine converter circuit blocks are indicated at 42 with the individual numbers (1-9) assigned thereto designating the respective number of the video bus line (V1 - V9) with which they are associated. As shown, these blocks are arranged juxtaposed in a row generally parallel with the multiplexing circuit 31 and its video bus lines and adjacent an edge of the device substrate 25. Power supply, timing signals and video information signals are supplied to the blocks from an external timing and control circuit, here shown at 45, which also supplies power and timing signals to the multiplexing circuit 31. The blocks are ordered numerically and their respective outputs 44, along which the video signals V1 to V9 are supplied, are connected to the appropriate bus lines 33 in the multiplexing circuit 31 at regularly - spaced locations, corresponding to the block spacings, rather than to the ends of these lines. The individual circuit blocks 42 generally occupy discrete and respective regions of the substrate surface, although of course certain components such as clock and power lines will be shared between blocks. Referring also to Figure 2, it will be appreciated that successive ones of the series of digital to analogue circuit blocks supply respectively successively - numbered video bus lines 33, and hence successive column conductors in the groups, i.e. C1 to C9, C10 to C18, etc. Such an arrangement has been found to lead to problems with the display quality. The cause of this has been identified as slight variations in the operation, and especially voltages generated in, different ones of the converter circuits due principally to the nature of the fabrication of the thin film elements constituting these circuits. A resultant variation in output voltage as supplied to the column conductors will tend to be greatest between converter circuit 1 and the converter circuit 9 in this example as these two converter circuits are spaced physically on the substrate 25 the furthest apart. These voltage variations can arise for a number of reasons but in general are due to variations in the operational characteristics of individual TFTs or dielectric layer thicknesses over the substrate, or from voltage losses along thin film signal lines feeding the converter circuits. Although the consequential variation of voltages tend to be the most significant with circuit blocks widely separated on the substrate, the variation in voltages produced in blocks physically closer together, and therefore whose thin film circuit elements are much less widely separated, will likely be minimal. Referring to Figure 2, it will be appreciated that the signals generated by the converter circuits 1 and 9 will appear, via the signal bus lines V1 and V9, on immediately adjacent columns of the display, i.e. on the last column conductor of one group and the first column conductor of the next group, (e.g. column conductors C9 and C10, C18 and C19, etc). Thus, assuming a uniform display field is intended, a difference in voltages applied to these columns will show up as steps in output brightness from the display elements across the display, and repeating with a pitch equal to the number of columns in each group. Such brightness steps would be highly visible. In order to reduce the visibility of the effect of such output voltage variations, and in accordance with a further feature of the invention, the lay-out of the converter circuits on the substrate is modified such that converter circuits which are to supply adjacent columns in the array are placed close together. The effect of this is to reduce the change in voltage which occurs moving from one column to the next, although the maximum voltage difference which can occur for columns in any one complete multiplexer group will be unchanged.
Figure 4 illustrates, for comparison with Figure 3, the lay-out of the column drive circuit components in one embodiment according to the present invention. From this figure, it is seen that the nine converter circuit blocks 1 to 9 are again arranged in series in a line parallel to the multiplexing circuit 30 but that the blocks 42 are arranged in a different, and particular, numerical order. Thus, the converter circuit blocks 1 and 9 are arranged physically immediately adjacent one another. The other blocks 2 to 8 are similarly arranged physically on the substrate 25 to reduce the effects of voltage variations. Hence, block 2 is arranged between blocks 9 and 8, rather than being widely separated from these blocks as in the Figure 3 arrangement, and so on. The complete sequence of the blocks, as shown in Figure 4, is 1 , 9, 2, 8, 3, 7, 4, 6 and 5, and it will be apparent that no two adjacent columns are therefore supplied with voltages from widely separated blocks.
Figure 5 illustrates schematically another possible arrangement of the column drive circuit components in accordance with the invention. This embodiment differs from the previous embodiment in that the converter circuit blocks 42 are laid out instead in two rows and with the blocks in one row being offset from those in the other in brick-like fashion but with the numerical order of the overlapping blocks in the direction of the rows being the same as before. In this case, the circuits blocks associated with some pairs of adjacent column conductors lie even closer together. The arrangement allows each block to occupy more space in the row direction, although a greater overall space in the column direction is required to accommodate the two rows of blocks.
With regard to the arrangements of Figures 4 and 5, then the lay-outs of the blocks 42 in both cases is such that differences in voltages generated in the video bus lines which connect to successive columns is as small as possible. The possibility of large voltage variations occurring from one column to the next is avoided. The more gradual change in voltage which can still occur over a number of columns is far less noticeable. Although the above-described example of display device utilises digital video signals supplied to the column drive circuit 35 and the circuit blocks 42 comprise digital to analogue converter circuits, each including an input latch circuits, the same technique is applicable to other kinds of column drive circuit which supply the necessary signals for the plurality of video bus lines in the multiplexing circuit. Thus, the column drive circuit may be of a type to which analogue video information is applied instead, in which case each of the circuit blocks 42 can comprise a sample and hold circuit with buffer amplifier, or other known form of analogue video signal processing circuit suitable for the required purpose. While the converter circuit blocks have been shown as arranged parallel to the multiplexing circuit between an edge of the display element array and an edge of the substrate 25, the same principles can be applied in the case where the circuits are located elsewhere on the substrate, for example closer to region where the externally provided video signal is supplied to the substrate. The blocks 42 could be arranged other than linearly in one or more rows. If the region of the substrate available to accommodate the circuit blocks allows, the blocks could be arranged in a square pattern or even in a curved line.
In the described embodiments, the column drive circuit 35 for the array comprises a single unit. However, and particularly if there is a relatively large number of column conductors to address, the column drive circuit may effectively be split into two separate (sub-) circuits, each of which would be similar to the previously described drive circuit 35 but addressing just one half of the set of column conductors, and with the two circuits operating simultaneously in parallel and generally independently, although controlled appropriately by the timing and control unit 45. By using separate column drive circuits in this manner, each with its separate set of video bus lines, faster operation becomes possible and problems due to the lengths of the video bus lines and their resistance are reduced since their individual lengths are now much shorter, for example corresponding approximately to half the row length.
In a colour display device, then assuming the pixels are arranged in RGBRGB etc. order in a row, the video signal bus lines V1 to V9 can supply red, green, blue, red, green, blue, etc. colour information, in which case the blocks 42 in the Figure 4 example would, starting at the left, operate with red, blue, green, green, blue, red, etc colour information respectively.
The active matrix display device may be of a type using display elements other than LC display elements for example, electroluminescent or electro-chromic display elements.
The invention is applicable also to other kinds of active matrix array devices in which it would be desirable to integrate more of the addressing circuitry, such as sensor array devices in which matrix sensing elements comprise, for example, optical sensing elements as in image sensing array devices, or pressure or capacitive sensing elements as in touch or fingerprint sensing array devices, and in which the matrix array of sensing elements are similarly addressed via sets of row and column conductors. Typical examples of an image sensing device and fingerprint sensing device are described in EP-A-0569090 and US-A-5325 442 respectively. In these types of devices, each row of the matrix elements is selected via an associated address conductor of one set and data from the elements of the selected row, usually in the form of electrical charges, is read out via respective conductors of the other set. The conductors of this other set can be coupled to a multiplexing circuit similar to that of Figure 2 and with the bus lines connected to respective associated sense amplifiers responsive to the element outputs. The sense amplifiers can be integrated, together with the multiplexing circuit, on the same substrate as the array of sense elements, and fabricated, using thin film technology, simultaneously with the sense element array, and with the individual sense amplifier circuit blocks being laid-out in the manner described to avoid problems caused by variation in the operational characteristics of the sense amplifier circuits which are situated further apart.
From reading the present disclosure, other modifications will be apparent to persons skilled in the art. Such modifications may involve other features which are already known in the field of active matrix array devices and component parts thereof and which may be used instead of or in addition to features already described herein.

Claims

1. An active matrix array device comprising an array of individually addressable matrix elements, first and second sets of crossing address conductors connected to the matrix elements, the array of matrix elements and the sets of address conductors being carried on a substrate, and an addressing circuit connected to the sets of row and column conductors for addressing the matrix elements which addressing circuit comprises a multiplexing circuit integrated on the substrate and connected to the first set of conductors and having a plurality, n, of signal bus lines, the address conductors of the first set being arranged in a series of groups with each group comprising n successive address conductors and the multiplexing circuit being arranged to couple sequentially each group of address conductors to the signal bus lines with each address conductor in a group being coupled to a respective one of the bus lines, the addressing circuit further including a respective signal processing circuit connected to each bus line, characterised in that the signal processing circuits associated with the bus lines are integrated as respective circuit blocks on the device substrate with the individual signal processing circuit blocks associated with adjacent column conductors being located close together on the device substrate.
2. An active matrix array device according to Claim 1 , characterised in that the order in which the signal processing circuit blocks are arranged physically on the device substrate is different to the physical order of the signal bus lines to which they are respectively connected.
3. An active matrix array device according to Claim 2, characterised in that the multiplexing circuit extends alongside one edge of the array of matrix elements and the signal processing circuit blocks are arranged in at least one row extending alongside the multiplexing circuit.
4. An active matrix array device according to Claim 1 , Claim 2 or Claim 3, characterised in that the matrix elements comprise electro-optic display elements.
5. An active matrix array device according to Claim 4, characterised in that the signal processing circuits comprise digital to analogue converter circuits.
6. An active matrix array device according to Claim 4, characterised in that the signal processing circuits comprise sample and hold circuits.
7. An active matrix array device according to Claim 1, Claim 2 or Claim 3, characterised in that the matrix elements comprise sensing elements each responsive to an input to produce an output signal along its associated address conductor of the first set.
8. An active matrix array device according to Claim 7, characterised in that the signal processing circuits comprise sense amplifier circuits.
PCT/EP2000/006982 1999-07-29 2000-07-19 Active matrix array devices with reduced non uniformities across multiplexed electrode groups WO2001009871A1 (en)

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KR20010106494A (en) 2001-11-29
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US7123232B1 (en) 2006-10-17
TW523728B (en) 2003-03-11
KR100700412B1 (en) 2007-03-27

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