RU2113765C1 - Receiver of base station of radio communication system using code channel separation - Google Patents

Abstract

FIELD: communication. SUBSTANCE: device has n arrays, each of which has heavy structure noise rejection unit 3, which first group of inputs is connected to outputs of reference signal conditioner 4; second group of inputs is connected to outputs of control unit 5. Output of rejection unit 3 is connected to first input of commutator 6, which second input is connected to input of rejection unit 3 and one of network outputs of interface 2. Third input of commutator 6 is connected to output of control unit 5. Output of commutator 6 is connected to input of receiver 1, which one output is connected to one of inputs of first group of inputs of control unit 5 for all arrays and to one of inputs of reference signal conditioners 4 for n-1 arrays. Second output of receiver 1 is connected through received signals level analyzer 7 to one input of second group of inputs of control unit 5 for all n arrays. This results in elimination of transmission of service information, decreased requirements for precision of power levels of antenna system, decreased number of power levels. EFFECT: increased stability to noise. 6 dwg

Description

 The invention relates to the field of radio communications and may find application in communication systems with code division multiplexing.

 Known receiving equipment of the central station (CA) asynchronous address communication system (AACC) "Kolos" (Pyshkin IM and other mobile radio communication systems. -M .: Radio and communications, 1986, p. 101), containing n receivers connected to the antenna through bridge blocks and antenna distributors, the disadvantage of which is low resistance to structural interference when it is used in AACC with broadband signals.

 A well-known code division multiple access system developed by Qualcomm ("Justification of the applicability of code division multiple access (SDMA) in relation to digital cellular systems and personal cellular networks", USA, Qualcomm, May, 1992). In this system, the base (central) station (BS) contains n receivers, each of which receives a signal from its mobile subscriber station (AC).

 The level of mutual (structural) interference on the BS in this system is reduced through the use of adaptive adjustment of the power of the AC signals. The disadvantages of this system are the low bandwidth, due to the need to exchange service commands between the BS and the AC in the process of adjusting the power of the AC signals, as well as the stringent requirements for the accuracy of setting the gradations of power.

 Closest to the proposed invention is the receiving equipment of the central station AACC "Trinket-1", developed by the Voronezh Research Institute of Communications (Technical Description "Complex of equipment AACC" Trinket-1 ", Voronezh, 1979).

 The structural diagram of the prototype is shown in figure 1, where it is indicated: 1 - receiving device, 2 - matching device, 3 - analyzer of the levels of received signals.

 The input of the device is the input of the matching device 2, the outputs of which are connected to the corresponding receivers 1. The information outputs of the receivers 1 are the outputs of the equipment, the other outputs of the receivers 1 are connected to the inputs of the level analyzer 3, the output of which is the output of the equipment.

 The device operates as follows. The input mixture containing signals from the speakers, through the matching device 2 is fed to the inputs of the receivers 1. In each of the receivers 1, the signal is processed from one of the n speakers. The signals from the outputs of the receivers 1 are fed to the inputs of block 3, where the levels of the received signals are measured and a decision is made about which of the received signals can have an unacceptable interfering effect on the reception of weak signals from remote speakers. Information about the measured levels from the output of the analyzer of levels 3 is fed to the output of the receiving equipment and then goes to the transmitter of the CA, which brings it to the corresponding speakers. In the AC, these commands adjust the power of the transmitters.

 The disadvantages of the prototype are the low throughput of the system, due to the need to transmit service signals, the inertia of the system, strict requirements for the accuracy of setting the gradation of power of the AC transmitters, a large number of gradations of power and the hardware complexity of their implementation, as well as the presence of restrictions on the minimum allowable distance between the CA and the AC, due to the finite number of gradations of the power of the transmitters AC.

 To eliminate these shortcomings, n receiving units of powerful signal interference, n shapers of a reference signal, n control units, n switches, (n - 1) analyzers of the levels of received signals are introduced into receiving equipment containing n receivers, a matching device, an analyzer of received signal levels, moreover, n outputs of the matching device are connected to the corresponding n lines, each of which contains a block of rejection of powerful structural interference, one group of inputs of which is connected to the outputs of the driver of the reference signals alov, the second group of inputs is connected to the outputs of the control unit, the output of the control unit is connected to the third input of the switch, the first input of which is connected to the output of the notch unit, the second input of the switch is combined with the input of the notch unit and connected to the corresponding output of the matching device, the output of the switch is connected to the input a receiver, one output of which is connected to the input of the analyzer of the levels of the received signal, and the second output is connected to the first group of inputs of all n control units and the corresponding input of each from (n-1) shapers of the reference signal, the outputs of the level analyzer of each line are connected to the second group of inputs of all n control units.

 The structural diagram of such a device is shown in Fig. 2, where it is indicated: 1 - receivers, 2 - matching device, 3 - block of rejection of powerful structural interference, 4 - driver of the reference signal, 5 - control unit, 6 - switch, 7 - analyzer of received levels signals.

 The input of the matching device 2 is the input of the equipment, and the outputs of the matching device 2 are connected to the inputs of n rulers, each of which contains a notch block 3, a switch 6, a receiver 1, a level analyzer 7. One of the inputs of the notch block 3 is combined with the second input of the switch 6 and connected to the output of the matching device 2.

 Each ruler also includes a reference signal generator 4, the outputs of which are connected to the first group of the input of the notch unit 3, and a control unit 5, whose outputs are connected to the second group of inputs of the notch unit 3. One of the outputs of the control unit 5 is connected to the third input of the switch 6 One output of the receiver 1 is connected to the first group of inputs of the control units 5 of all n lines (inputs "Synchronization signal" (CC)) and to the inputs of the drivers of the reference signals 4 (n - 1) of the line (inputs CC). The second output of the receiver 1 through the level analyzer 7 is connected to the second group of inputs of the control units 5 of all n lines (inputs "Exceeding the threshold" (PP)).

 The equipment operates as follows.

 The system uses noise-like phase-shifted signals (FM SHPS) operating at the same carrier frequency and in the common frequency band. The system uses code division multiplexing, in which the address feature of the speaker system is the structure of the memory bandwidth.

The input mixture from the input of the equipment through the matching device 2 is fed simultaneously to n rulers. In each of the n lines, the input mixture goes directly to the first input of the switch 6, and to the second input through the notch block 3, where powerful signals from nearby speakers whose receivers are in synchronism with their signals are notched. The rejection of structural (intra-system) interference in the rejection unit 3 of this receiver occurs using the reference signal 4, using commands about the presence or absence of synchronization of other (n-1) -th receiver equipment with their speakers. These commands are called sync signals (CC). Thus, the notch block 3 _{1 of the} first line receives synchronization signals from the receiver 2, 3,. .., n, i.e. CC ₂ , ... CC _n . The CC commands generated in each of the receivers from its second output also arrive at the second inputs of the control unit 5 of each of the rulers.

 From the output of the switch 6, the signal is fed to the receiver 1. The signal received by each of the receivers is measured by the level in the level analyzer 7 (for example, by comparison with the selected threshold). Information about the levels of the received signals, about exceeding or not exceeding the set threshold (PP), from the output of this receiver goes to the control unit 5 of all other lines. In the case when in the equipment none of the receivers received a powerful signal, the input mixture goes directly to the inputs of all the receivers. In this case, the control unit 5 provides the connection of the output of the matching device 2 through the switch 6 to the input of the receiver.

 In the event that the level of signals received in receivers synchronized with their speakers measured in the level 7 analyzer turned out to be unacceptably large and can interfere with the reception of signals from more distant subscribers, in each line the control unit 5 is connected using a switch 6, the input of the receiver, not included in synchronism, to the output of the notch block 3. In the notch block 3, using the reference signals generated in the formers of the reference signals 4, the powerful signals of other receivers included in the sync are rejected chronism.

 Thus, in the proposed equipment of the base station, simultaneous reception of signals from nearby speakers is provided, the spread of the levels of which is less than the base (B) of the NPS. In this case, the level of structural interference does not exceed the permissible value, and the signals are separated in shape.

 After entering the synchronism of receivers with nearby speakers, in the event that the level of their signals turned out to be unacceptably large and does not allow other receivers receiving signals from more distant speakers to enter synchronism, these powerful signals are rejected at the inputs of these other receivers, which ensures the ability to operate BS equipment with both near and remote speakers.

 The application of such a solution allows either to refuse to adjust the power of the AC transmitters, or to reduce the number of gradations of the power of the AC transmitters and reduce the requirements for the accuracy of setting the power gradation. This will lead to an increase in the throughput of the communication system with code division of channels, since the use of power control and a large number of its gradations requires a lot of time for exchanging service information, making the system inertial.

 The equipment provides independent operation of each of the speakers with its own receiver without receiving service information from the base station. The notion of powerful signals at the inputs of receivers that receive weaker signals removes restrictions on the minimum allowable distance between the speakers and the CA, which increases the operational and tactical characteristics of the system.

 Consider the hardware implementation of some blocks.

 The block diagram of the notch block 3 is shown in figure 3, where it is indicated: 31 - multiplier (modulator), 32 - notch filter, 33 - multiplier (remodulator), 34 - bandpass filter tuned to the carrier frequency and having a band equal to the frequency band of the transmitted ШПС, 35 - attenuator, 36 - delay element, 37 - switch, 38, 39 - adjustable delay elements (used if necessary).

Each notch block (for example, 3 ₁ ) contains (n-1) identical rulers connected to the input of the notch block 3 through an adjustable delay element 39. Each ruler has its own reference signal (OS), so OC ₂ is fed to the 1st cell - a reference signal that ensures the convolution of the NPS transmitted for the second receiver 1 ₂ , and OC _n is fed to the nth cell; a reference signal that provides the convolution of the NPS transmitted for the receiver 1 _n .

In addition, for each line from the output of the control unit 5, a corresponding command for turning on the line (VK) is supplied. In the notch block 3, these commands are used to control the switches 37. The input mixture containing the useful SHPS 1 intended for the given receiver 1 ₁ and the sum of the interfering ShPS from other speakers is fed to the input of the line. The input of the first line from the output of the control unit 5 receives the command VK ₂ . In the event that BK ₂ takes the value "0", the switch 37 ₁ connects the input of the ruler to its output through the delay element 36 ₁ , in the case of BK ₂ takes the value "1", the input of the ruler is connected to its output (the output of the switch 37 ₁ ) through series-connected blocks 31 ₁ -37 ₁ .

OC ₂ is supplied to the second input of block 31 ₁ from the output of shaper 4, while OC ₂ is synchronous with ШПС ₂ , transmitted by AC ₂ for receiver 1 ₂ . Due to the multiplication with a synchronous reference signal, the SHPS _{2 is} collapsed into a narrow-band signal, which is rejected in the notch block 32 ₁ . At the same time, the remaining SHPS, which are part of the input mixture, pass to the output of the multiplier 33 _{1 with} virtually no distortion, because in the multiplier 31 _1, manipulation is imposed on them according to the law OC ₂ , and in the multiplier 33 ₁ it is removed due to multiplication with the same OC ₂ .

The input mixture, from which SHPS ₂ is excluded, is filtered in the filter 34 ₁ and through the attenuator 35 is fed to the input of the switch 37 ₁ .

 The rest of the lines work in a similar way.

Adjustable delay elements 38 and 39 are used to ensure the synchronization of the input and reference SHPS, the delay element 36 is used to ensure the same signal propagation time on both branches of the notch unit 3. This is done to connect or disconnect the blocks 31-35, performing rejection of powerful interference , did not lead to a violation of synchronism in the receiver 1 ₁ .

 The receiver 1 can be made as shown in ed. N 300946, cl. H 03 C 3/40. In this case, the structural diagram of the AC transmitters should correspond to the structural diagram of the transmitter according to N 300946.

 Figure 6 presents the structural diagram of the receiver 1, where it is indicated: 61 - synchronization device, 62, 66 - multiplier (remodulator), 63 - orthogonal PSP driver, 64 - phasing device, 65 - reference PSP generator, 67, 69 - band-pass filter , 68 is a phase detector.

With this design of the receiver 1, the synchronization signal (SS) necessary for the operation of the claimed equipment, a synchronization device 61 is formed, the output of which is the output of the receiver 1, the command SS can take the values "1" or "0". From the output of block 67, the signal is supplied to a level analyzer 7 ₁ , where the convoluted signal is detected and compared with a threshold. At the output of the level analyzer 7 ₁ , a PP command is generated (threshold exceeded), which can take the value “1” or “0” depending on the threshold being exceeded or not exceeded, respectively.

The reference signal generator 4 ₁ , which is part of the first ruler and generates OC ₁ for notch block 3 ₁ , consists of (n-1) independent devices, each of which generates its own reference signal OC. Each device has its own SS command and each device uses its own SRP generators similar to the SRP generators of the respective receivers (1 ₂ .. .1 _n ).

The structural diagram of one device (see figure 4), which is part of FOS 4, is shown on the example of a device forming OC ₂ . Figure 4 indicates: 41 - the local oscillator frequency generator, 42 - the orthogonal PSP driver, 43 - the PSP generator, 44 - the 90 ^o phase shifter, 45, 46 - the multiplier (modulator), 47 - the adder, 48 - the adjustable delay element.

 The device is built similarly to the transmitter on autosw. N 300946 with the difference that the synchronization of the blocks 42 and 43 is carried out not using the phasing device, but using the synchronization signals (CC) supplied to their inputs through an adjustable delay element 38, used to ensure the input and reference signals are in phase in the notch block 3 .

 The structural diagram of the control unit 5 is presented in figure 5, where it is indicated: 51 - circuit I, 52 - circuit OR, 53 - inverter, 57 - key.

Let us explain the operation of the control unit by the example of block 5 ₁ , which is part of the first ruler.

The PP and SS commands from each level analyzer 7 and receiver 1 are sent to the AND 51 circuits. The command generated at the output of the And 51 ₁ circuit, to which the PP ₁ and SS ₁ commands _of this receiver 1 ₁ are located, is in the same line with the control unit 5 ₁ , through the inverter 53 is supplied to the key 54. The key 54 is opened if this receiver 1 _{1 has} not entered synchronism and the level of the signal received by it has not exceeded the threshold. Schemes And 51 ₂ -51 _n , to which commands are issued PP and SS from receivers 1 ₂ - 1 _n , form the command to turn on the lines VK ₂ - VK _n , which are fed to the inputs of the notch block 3 ₁ . Thus, if the receiver has entered synchronism and the level of the signal it received has exceeded the threshold, then the corresponding line in block 3 is turned on, and switch 6 will connect block 3 to the receiver input if at least one of the VCs takes the value “1”.

 The switch 6 is a typical element and can be performed, for example, on the chip 564KP1, which is a set of keys, while using two keys, the outputs of which are combined. The command is sent directly to the control input of one of the keys, and through the inverter to the other.

 The level analyzer 7 can be made in the form of a series-connected detector and a comparison circuit with a fixed threshold.

Claims (1)

 The receiving equipment of the base station of the radio communication system with code division multiplexing, containing n receivers, a matching unit, an analyzer of levels of received signals, characterized in that n blocks of rejection of powerful structural interference, n shapers of reference signals, n control units, n switches and n - 1 are introduced analyzers of the levels of received signals, and the receiving equipment of the base station is made in the form of n rulers, in each of which the outputs of the driver of the reference signals are connected to the first group of inputs of the notch block m sensible structural interference, the second group of inputs of which is connected to the outputs of the control unit, the output of the rejection unit of powerful structural interference is connected to the first input of the switch, the second input of which is combined with one of the inputs of the rejection unit of powerful structural interference and connected to one of the n outputs of the matching unit, the third the input of the switch is connected to the output of the control unit, and the output of the switch is connected to the input of the receiver, one output of which is connected to one of the inputs of the first group of inputs of the control units of n rulers and one of the inputs of the of reference signals of the (n - 1) line, the other output of the receiver through the analyzer of the levels of received signals is connected to one of the inputs of the second group of inputs of the control unit of n rulers.

Images