DE19648178A1 - Radio telephone system using preset frequencies - Google Patents

Abstract

The system includes at least two repeater (5,6) which convert a frequency onto another one within a system frequency band. Preset frequencies for the radio telephone system are within the frequency band. The system also includes at least one transceiver (1). The modulation frequency position is a mirror image on the frequency axis of the other frequency. Preferably, the first repeater (5) converts the preset frequency (f11,12) onto the other frequencies (f22,21) for communication with the transceiver, while the other repeater (6) reverses the frequency conversions of the first repeater.

Description

The invention relates to a system for wireless telephony with a suitably adapted cellular repeater and a Radio communication method for wireless telephony.

Wireless telephone networks (cellular networks) are increasing worldwide as digital GSM, DCS, CDMA or PCS networks operated. Here denote GSM, DCS and CDMA Standards in which the framework conditions of the networks, in Especially for the radio interface with the radio spectrum the carrier frequencies, carrier spacing and bandwidth, Modulation type and position, presentation and coding of the data with the so-called framing for synchronization, carrier and Channel designation and control are defined. Any network has a number of base stations, each of which a local area (cell / sector) provided. The division of a network into cells / sectors is done to provide adequate illumination and sufficient Capacity for local traffic at the best possible Realize exploitation of the radio spectrum. Each Cell / sector will be local according to the expected Traffic is allocated a limited radio spectrum that with the exception of CDMA operation from the spectrum in the neighboring cells / sectors different and not immediately adjacent cells / sectors also repeated is assigned.

The carrier names used in the respective system (Numbers) are coded to those in the sector Terminals, e.g. B. mobile phones, and are the correspondingly defined frequencies in the downlink and Assigned uplink paths. The downlink path describes this  Frequency band on which the transmission from the base station to the end devices. The uplink path designates accordingly the frequency band on which the transmission from the Terminal devices to the base station.

The GSM standard z. B. stipulates that the terminal on the so-called Broad Cast Channel (BCCH) of the assigned Network operator and there the available at the location Channel numbers of the cell and the carrier numbers of the BCCH from adjoining cells. Because a channel number is one certain frequency and a certain period of time the terminal can be assigned to the channel number Select the associated frequency.

To supply poorly lit areas, e.g. B. tunnels, skyscrapers etc., so-called mobile radio repeaters are used in one sector, which are considerably cheaper than a base station. Repeaters are used for radio coverage of shadowed and insufficiently covered areas, especially for country roads and motorway routes in forested areas where coverage of the surrounding areas appears unnecessary. Conventional mobile radio repeaters, such as those used for. B. in "Repeater for Mobile Communications" by J. Steffke and H. Mühlbauer in a company information of Kathrein-Werke KG Rosenheim, take up the signal to be spread by a first antenna, amplify it and radiate the signal by a second antenna same carrier frequency in the otherwise insufficiently supplied area. The functional structure of conventional repeaters is shown in FIG. 3. In principle, these are bidirectional, linear amplifiers.

Channel-selective and band are special embodiments selective repeater known.

In the case of a channel-selective repeater, this becomes high frequency signal mixed to an intermediate frequency and only one at a time Channel filtered. This requires a high selectivity of the Filtering, since only the desired channel is filtered and filtered should be emitted. To avoid interference therefore, if possible, two channels between two active ones Keep frequencies free.

Band-selective repeaters, however, filter an entire frequency band with several channels on an intermediate frequency and ver strengthen it. This is also a high selectivity Filtering required to avoid interference at the band limits avoid.

The problem with linear repeaters now is that feedback lead to fatally disturbing influences via the two antennas can. That is why the antennas in the linear repeaters must be used be decoupled. This can e.g. B. happen in that they can be attached to two different house fronts and radiate away from each other, so that building structure between the Antennas located. The repeater should be reinforced be at least approx. 15 dB smaller than the achievable one Decoupling. However, if these conditions are not met the gain between the transmitting and receiving antennas is greater than the attenuation due to the spatial decoupling the antennas, then there is a fatally disturbing feedback.

There are two antennas for decoupling linear repeaters required, which are also arranged apart from each other have to be and causes high costs. The installation and Maintenance is also quite high because of the  Field strengths in the vicinity of a repeater carefully measured and the repeater has to be adapted elaborately. Nevertheless, the arrangement of linear repeaters remains unstable because vehicle moving in the feedback path and seasonally changing foliage of trees or buildings the feedback characteristic changed greatly.

task

Based on this state of the art, it was the task of Invention, for inexpensive and reliable supply a system for wireless telephony of mobile devices with an appropriately adapted cellular repeater create and a corresponding procedure for radio coverage to specify for wireless telephony.

The task is carried out by the invented system with the characteristics of claim 1, by the repeater with the features of Claim 4 or solved by the method according to claim 1.

Advantageous embodiments are in the subclaims described.

Since the channel number in the network standard is fixed in relation to a Carrier frequency is, can be in digital systems conventional implementation of the frequency by a cellular re peater to serious malfunctions with the end devices to lead. However, it is desirable to convert the frequency because then a spatial decoupling of the two antennas and Careful coordination of the repeater with the local one prevailing signal level can be omitted.

The invention therefore provides that the carrier frequency by a first conversion to another frequency in the same band to implement. By using a frequency in the same  Band of the network operator does not apply and Approval of a special frequency for the repeater. But however, the frequency conversion creates a first one Problem by the endpoints the information on the implemented frequencies with the non-standard Evaluate the assignment and then react incorrectly.

According to the teaching, to eliminate this first problem is the Invention provided the frequency of the modulation to mirror in addition. This means that one on the decoder Receiver inverted the information characters. "0" becomes "1" and vice versa. So the transferred Information for standard devices no longer makes sense because they are not system-compliant. Consequently, they are considered one Foreign interference is now ignored in accordance with the system.

A second problem arises from the fact that almost every recipient it is also possible to receive an image frequency where he unwanted the position of the modulation before Evaluation reverses. A device receives the after the apprenticeship of the invention implemented signal with the mirrored Modulation as image frequency, then arises in the end device nevertheless a standard evaluable signal, so that a unwanted reactions of the terminal no longer can be excluded.

Usually in the receivers of the terminals Frequencies of the mixer oscillators above the receiving frequencies placed. That is why signals in the lower part of the band from these terminals Mirror selection received unintentionally and the second problem with the unwanted reactions can be avoided if the signals generated according to the teaching of the invention in the lower part of the band are transmitted.  

drawings

The invention is explained with the accompanying drawings.

Show it:

Fig. Mobile radio system 1 with the transmitting / receiving stations for a fixed frequency band and at least two mobile radio repeaters;

Figure 2 shows the area division into sectors with a corresponding frequency allocation.

Fig. 3 shows a conventional mobile radio repeater;

FIG. 4 shows the implementation of the n-th channels to the 1-th channels of the corresponding frequency band of the respective uplink and downlink path;

FIG. 5 shows the implementation of the n-th channels of the frequency band of the uplink and downlink path to the 1-th channels of the frequency band of the downlink or uplink path;

Fig. 6 shows a mobile radio repeater for converting the received NEN frequency to another frequency in the same frequency band and for mirroring the frequency position.

Embodiment

In Fig. 1 the mobile radio system is shown with transmitting / receiving stations 1 , 2 and 3 , which are networked with each other by cable or directional radio links 4 and work in a fixed frequency band. The system has at least two mobile radio repeaters 5 , 6 . The terminals 7 of the system in a sufficiently supplied area have a direct radio connection with the base station 1 for the corresponding sector. The base station 1 transmits on the frequency f _{11 of} the nth channel of the downlink path of the frequency band and receives the messages of the terminal 7 on the frequency f _{12 of} the nth channel of the uplink path of the frequency band. The first mobile radio repeater 5 communicates on the same frequencies as the terminal 7 with the base station 1 of the sector. It is used to convert the frequency f _{11 of} the downlink path to the frequency f ₂₂ , the frequency f ₂₂ preferably being the 1st channel of the frequency band. Accordingly, the frequency f _{21 of} the 1st channel of the frequency band of the uplink path is converted to the frequency f ₁₂ . In addition to the frequency conversion, the frequency position of the modulation is mirrored. The signals on the 1st channels in the downlink and uplink path of the frequency band with the frequencies f ₂₂ and f ₂₁ thus have no usable information content for terminal devices, so that the terminal devices do not adapt to them either.

So that the information can be received especially from the terminals 8 in areas that are poorly illuminated by the base station 1 of the sector, a second ter mobile radio repeater 6 is provided, which reverses the previously described implementation. Its antenna is aimed so that it supplies the area that is directly poorly illuminated by the base station.

The division of a supply area into sectors is shown in FIG. 2. Each sector has a base station which is based on a fixed carrier frequency f ₁ , f ₂ ,. . . f _n , the frequency band of the system is operated. Sectors that are operated on the same channels are spaced as far apart as possible in order to avoid mutual interference.

The difference between the proposed mobile radio repeaters 5 , 6 and conventional mobile radio repeaters can be seen in FIG. 3. There is shown a conventional mobile radio repeater that communicates with a first antenna 9 with the base station on the frequency pair f ₁₁ , f ₁₂ . The connec tion to terminals is carried out with a second antenna 10 , which is also operated on the frequency pair f ₁₁ , f ₁₂ . Duplex filters 11 and 12 are provided for frequency separation. The signals are amplified in amplifiers 13 and 14 . Since both antennas 9 , 10 are operated with the same frequency pairs f ₁₁ , f ₁₂ , the antennas 9 , 10 must be sufficiently decoupled. In the proposed in the invention mobile radio Re peaters 5 , 6 decoupling is no longer necessary since different frequency pairs f ₁₁ , f ₁₂ and f ₂₁ , f ₂₂ are used.

The implementation of the channels by the mobile radio repeaters 5 , 6 is shown in FIGS. 4 and 5.

A first alternative is outlined in FIG. 4. The signal transmission takes place for each sector on a carrier pair n of the frequency band for the uplink and the downlink path. The first mobile radio repeater 5 converts the nth carrier pair of the frequency band of the downlink or uplink path to the 1st carrier pair of the frequency band of the corresponding path. For the other path, the 1 st pair of carriers is converted to the n th pair of carriers. The signals are received for implementation by receivers E and emitted by transmitters S.

A second alternative is outlined in FIG. 5, in which the nth carrier of the downlink path is provided for the first mobile radio repeater 5 , on the 1st carrier of the uplink path and the nth carrier of the To implement the uplink path on the 1st carrier of the downlink path.

In both cases, the second mobile radio repeater 6 resets the signal accordingly.

In Fig. 6, the proposed in the invention mobile radio repeater for converting the received frequency to another frequency in the same frequency band and for mirroring the frequency situation is outlined. Communication between the base station and the end devices takes place in the downlink and uplink path at frequencies f ₁₁ and f ₁₂ . The input signals of the frequency f _{11 of} the downlink path are amplified in a first input amplifier 15 and converted and mirrored to the frequency f ₂₂ with a first mixer 16 and a first local oscillator 17 . A first filter 18 serves to suppress undesired mixed products. The signal is then amplified and emitted by a first output amplifier 19 .

Accordingly, the input signals of the converted frequency f _{21 of} the uplink path are amplified in a second input amplifier 20 and converted and mirrored to the frequency f ₁₂ with a second mixer 21 and a local oscillator 22 . A second filter 22 serves to suppress undesired mixed products. Then the signal is amplified by a second output amplifier 23 and emits abge. To separate the carrier frequencies, a duplex filter 25 is inserted between the antenna 24 and the repeater circuit 15-23 , as is also used in conventional mobile radio transmitters.

Claims (8)

1. System for wireless telephony on fixed frequencies in a frequency band with at least one transmitting / receiving station ( 1 ) and with at least two repeaters ( 5 , 6 ), characterized in that the repeaters ( 5 , 6 ):

• 1) convert one frequency to another frequency within the frequency band of the system and
• 2) reflect the frequency position of the modulation on the frequency axis of the other frequency.

2. System according to claim 1, characterized in that a first repeater ( 5 ), the respectively defined frequencies (f ₁₁ , f ₁₂ ) for communication with the transmitting / receiving station ( 1 ) to other frequencies (f ₂₂ , f ₂₁ ) within the frequency band of the system and a second repeater ( 6 ) reverses the frequency conversions of the first repeater ( 5 ). 3. System according to one of the preceding claims, characterized in that the repeaters ( 5 , 6 ) convert a frequency to the edge region of the frequency band. 4. Repeater ( 5 , 6 ) for receiving, amplifying and transmitting radio signals in a defined frequency band, characterized by

• 1) a converter for one frequency to another frequency within the frequency band of the system and
• 2) a device for mirroring the frequency position of the modulation on the frequency axis of the other frequency.

5. Repeater ( 5 , 6 ) according to claim 4, characterized by a circuit for mixing an input signal and for selecting a frequency-shifted mixed product, which has the mirrored modulation position. 6. Repeater ( 5 , 6 ) according to claim 4 or 5, characterized by:

• 1) two parallel input amplifiers ( 15 , 20 ) for the input signals,
• 2) a mixer ( 16 , 21 ) at the outputs of the input amplifiers ( 15 , 20 ),
• 3) a bandpass filter ( 18 , 22 ) at the outputs of the mixers ( 16 , 21 ),
• 4) an output amplifier ( 19 , 23 ) at each of the outputs of the filters ( 18 , 22 ), the outputs of the output amplifiers ( 19 , 23 ) being connected together to form an output signal,
• 5) at least one oscillator ( 17 , 22 ) connected to the mixers ( 16 , 21 ), wherein
• 6) the mixers ( 16 , 21 ) each convert one frequency (f ₁₁ or f ₂₁ ) of the input signal to another frequency (f ₁₂ or f ₂₂ ) within the frequency band of the system and
• 7) reflect the frequency position of the modulation on the frequency axis of the other frequency (f ₁₂ , f ₂₂ ).

7. A method for wireless telephony on fixed frequencies in a frequency band with at least one transmitting / receiving station ( 1 ) and with at least two repeaters ( 5 , 6 ), characterized in that

• 1) a frequency is converted to another frequency within the system frequency band and
• 2) the frequency position of the modulation is mirrored on the frequency axis of the other frequency.

8. The method according to claim 7, characterized in that in a first repeater ( 5 ) the respectively defined frequencies (f ₁₁ , f ₁₂ ) for communication with the transmitting / receiving station ( 1 ) to other frequencies (f ₂₂ , f ₂₁ ) are implemented within the frequency band of the system and the frequency conversions of the first repeater ( 5 ) are reversed in a second repeater ( 6 ).