RU2155446C1 - Receiving equipment of base station of communication system with coded channel separation - Google Patents

Abstract

FIELD: radio engineering, applicable in communication systems with coded channel separation. SUBSTANCE: estimation of interfering signals from other system parties is formed at the input of each receiver of the base system of cellular communication system with the use of which the structureborne noise of 20 to 40 dB is suppressed. EFFECT: enhanced noise immunity to structureborne noise. 3 dwg

Description

 The invention relates to radio engineering and can be used in communication systems with code division multiplexing.

 Known devices for receiving broadband signals in which the suppression of structural interference described in US Pat. NN 2000666, 2000665, 2042271, 2038697, H 04 B 1/10.

 The disadvantage of these devices is the low noise immunity to structural interference.

 Closest to the proposed is the equipment described in the monograph by I. M. Teplyakov and others. "Radio transmission systems", M., "Radio and communication", 1982, p. 49, Fig. 37, adopted as a prototype.

The structural diagram of the prototype is shown in figure 1, where the following notation is used:
1 ₁ - 1 _N - receiver,
2 ₁ - 2 _N - demodulator,
3 ₁ - 3 _N - amplifier,
4 ₁ - 4 _N - modulator,
5 - switch
6 - control unit.

 The prototype contains N rulers containing serially connected receiver 1, demodulator 2, switch 5, modulator 4, amplifier 3, while the output of amplifier 3 is connected to the input of receiver 1, and the output of control unit 6 is connected to the corresponding input of switch 5.

 The prototype works as follows.

Subscriber signals are received by receivers 1 ₁ - 1 _N , demodulated in N demodulators 2 and fed to the inputs of switch 5, which commutes them according to the commands received from control unit 6, to the information inputs of modulators 4 ₁ - 4 _N. Then the signals are amplified in blocks 3 ₁ - 3 _N. The combination of the inputs of the receivers 1 ₁ - 1 _N with the corresponding outputs of the amplifiers 3 ₁ - 3 _N provides a simplex mode of operation.

 The disadvantage of the prototype is the low noise immunity to structural interference.

 To eliminate this drawback, an adder and a matching device are introduced into a device containing a serially connected control unit and a first switch, as well as N identical rulers, each of which contains a serially connected receiver and a demodulator, a modulator and an amplifier, and sequentially connected to each of the N lines connected the first delay element, the subtractor and the second switch, as well as the second delay element and the synchronous-phase filter. Moreover, the output of the second switch is connected to the input of the receiver, the output of the demodulator is connected to the input of the modulator and is one of the N outputs of the device, the output of the amplifier is connected to one of the N inputs of the first switch, N outputs of which are connected through the corresponding second delay elements to the corresponding inputs of the adder, the output of which connected to the input of the synchronous-phase filter of each of the N lines. The output of the synchronous phase filter is connected to another input of the subtractor. The other input of the synchronous-phase filter is connected to the output of the first delay element, the input of which is combined with one of the inputs of the second switch and connected to the corresponding output of the matching device. In addition, one of the inputs of the receiver is connected to the corresponding input of the control unit, and the other output of the receiver is simultaneously with the corresponding inputs of the control unit and modulator. One of the outputs of the control unit is connected to one of the inputs of the second switch.

The structural diagram of the proposed device is shown in figure 2, where indicated:
1 ₁ ... 1 _N is the first delay element,
2 ₁ ... 2 _N - subtractor,
3 - the first switch
4 ₁ ... 4 _N - receiver,
5 ₁ ... 5 _N - demodulator,
6 ₁ ... 6 _N - modulator,
7 ₁ ... 7 _N - amplifier,
8 ₁ ... 8 _N - the second switch,
9 - adder
10 ₁ ... 10 _N - phase-synchronous filter,
11 - control unit
12 - matching device
13 ₁ ... 13 _N is the second delay element.

The proposed device contains N identical rulers, each of which contains a first delay element 1, subtractor 2, second switch 8, receiver 4, demodulator 5, modulator 6, amplifier 7, the output of which is connected to one of the N inputs of the first switch 3, corresponding the output of which through the second delay element 13 is connected to the corresponding input of the adder 9, the output of which through the synchronous-phase filter 10 is connected to one of the inputs of the subtractor 2, the other input of which is connected to the corresponding input of the sync a phase filter 10. Moreover, one of the inputs of the second switch 8 is simultaneously connected to the input of the first delay element 1 and to one of the N outputs of the matching device 12. The corresponding outputs of the control unit 11 are connected to the corresponding inputs of the first 3 and second 8 switches. One of the outputs of the receiver 4 is connected to the corresponding input of the control unit 11, and the other output of the receiver 4 is connected simultaneously with one of the inputs of the control unit 11 and the other input of the modulator 6. In addition, the outputs of the demodulators 5 ₁ ... 5 _N are outputs of each line.

 The proposed device operates as follows.

 The inventive device is the receiving equipment of the base station of the communication system with code division multiplexing, containing N receivers, each of which receives a signal from its subscriber communication. Subscriber stations use broadband phase-shift keyed signals that differ in pseudo-random sequence structures used in the formation of broadband signals.

 The input signal through the matching device 12 is supplied to the inputs of N identical lines (N is the number of subscriber stations). In each line, the input signal arrives at the input of the switch 8 directly or through a series-connected delay element 1 and a subtractor 2. The switch 8 is controlled by the control unit 11. From the output of the switch 8, the signal enters the receiver 4, and then to the demodulator 5, the information output of which is device output.

 In subtracter 2, the estimate of the total structural interference, which is a mixture of signals of the near subscribers of this system, whose level exceeds the permissible value, is subtracted from the input mixture.

 The formation of structural interference estimates is carried out in each of the N channels as follows. From the output of the receiver 4, the synchronization signal (a command that determines the initial phase of the generator of the pseudo-random sequence of the receiver 4) is supplied to the first input of the modulator 6, to the second input of which an information signal is supplied from the output of the demodulator 5. In the modulator 6, a copy of the received signal is generated using amplified in the amplifier 7 and fed to the first switch 3. Using the control unit 11, the switch 3 connects the output of this line (the output of block 7) to the corresponding delay element 13 while If the signal level received by the receiver of the line exceeds the permissible value. Thus, at the output of the adder 9, a mixture of signals of near subscribers is formed, the levels of which exceed the permissible value and therefore are structural interference for subscribers distant from the base station.

 This mixture is fed to the reference input of the synchronous-phase filter 10, the signal input of which is supplied with voltage from the input of the subtractor 2. Block 10 provides automatic adjustment of the phase and amplitude of the interference estimate. From the output of the filter 10, the structural interference assessment is fed to the second input of the subtractor 2, where it compensates for the structural interference in the input mixture.

 Blocks 1 and 2 are connected to the input of receiver 4 only if at least one or more structural interference occurs, and receiver 4 of this line either has not entered synchronism or has entered synchronism, but the level of signal received by it does not exceed the permissible value. Otherwise, the signal from the output of the matching device 12 is fed directly to the input of the second switch 8. Control by the specified algorithm is carried out by the control unit 11.

 Let us dwell on the hardware implementation of the introduced blocks.

The structural diagram of the control unit 11 is shown in figure 3, where indicated:
31 ₁ - 31 _N - comparison block with a threshold,
32 ₁ - 32 _N , 34 ₁ - 34 _N - element "And",
33 ₁ - 33 _N - inverter,
35 - element "OR".

 Block 11 contains N channels, each of which contains a series-connected comparison unit with a threshold 31, an “And” element 32, an inverter 33, an “And” 34 element, the output of which is connected to the corresponding input of the switch 3. In addition, the output of the “And” element 34 is connected to the corresponding input of the OR element 35, the output of which is connected to one of the inputs of the AND element 34. The connection point of blocks 32, 33, 35 is the second output of the control unit 11 and is connected to the corresponding input of the first switch 3.

 Consider the operation of the control unit 11 at different values of the input signals.

 In the case when the synchronization signal takes the value "1" and the level of the received signal exceeds the threshold in the comparison unit with threshold 31, the "1" command is generated at the output of the "And" 32 element, which is fed to the control input of the first switch 3 and connects the output this channel at the input of the corresponding second delay element 13. This means that this channel is involved in the formation of the interference estimate. The same command "1" is inverted in the inverter 33 and enters the block 34, the second input of which gives a command from the output of the block 36. Block 35 generates at its output "1" if there is a "1" at the output of block 32 of at least one of the channels . In this case, "0" is formed at the input of block 34 of this channel. Switch 8 in the presence of "0" at its control input connects the output of block 12 to the input of receiver 4, that is, in this channel, in this case, interference compensation is not performed.

 If at least one command “0” is present at the inputs of block 32 in this channel, and “1” is formed at the output of block 35, then “1” is formed at the output of block 34 and switch 8 connects a subtractor 2 to the input of receiver 4, while the input of this receiver 4 is compensated for structural interference. At the same time, in this case, “0” is present at the output of block 32, which is fed to the control input of block 3. At the same time, this channel is disconnected from the corresponding input of block 13. That is, it does not participate in the formation of the structural interference estimate.

 The first switch 3 contains N keys. An output of the corresponding channel is connected to the information input of each key, and a command is sent to the control input from the corresponding output of the control unit 11.

 Receiver 4 is a typical correlation receiver for broadband signals (for example, “Noise-like signals in information transmission systems” edited by VB Pestryakova, M., Sov.radio, 1976, p. 193, Fig. 6.21). The synchronization signal in the receiver 4, supplied to the blocks 11 and 6, is a “1” or “0” command generated by the search and synchronization device of the receiver 4 for setting the initial phase of its pseudo-random sequence generator. This command is sent to blocks 11 and 6.

 To generate a signal characterizing the level of the received signal supplied to block 11 in the receiver, for example, an additional correlation channel containing a multiplier, a filter, a logarithmic amplifier, and a detector included in the path not covered by the AGC system can be used.

 Modulator 6 is a broadband signal shaper and can be built in any known manner. In this case, the initial phase of the pseudo-random sequence generator used in generating the broadband signal is set by the synchronization signal of block 4, and the information signal supplied to block 6 is the information signal allocated by receiver 4.

 Block 10 can be performed as shown in the monograph V.M. Svistova "Radar signals and their processing", M., "Sov.radio", 1977, p. 127, Fig.3.5.

 At the output of block 10, only those noises pass, copies of which are contained in the reference signal, while their amplitudes and phases coincide with the amplitudes and phases of the noise supplied to the signal input of block 10, that is, with the amplitudes and phases of the corresponding noise in the input mixture. This ensures effective interference compensation.

 Block 13 is adjustable and serves to compensate for spreads in signal delays in N channels, ensuring their alignment.

 Block 12 provides matching the output of the antenna with the inputs of the receivers and can be made in the form of decoupling N resistors connected to the output of the antenna.

(см. "Шумоподобные сигналы в системах передачи информации", В.Б. Пестряков и др., М., "Сов.радио", 1973, стр.118).The prototype device has a low noise immunity to structural interference in the communication system with mobile subscribers when used in the system of broadband signals with code division multiplexing. Indeed, the allowable level of one structural interference when using noise-like signals is determined by the ratio:

(see. "Noise-like signals in information transmission systems," VB Pestryakov et al., M., Sov.radio, 1973, p. 118).

В то время, как динамический диапазон сигналов в системе связи с подвижными абонентами может составлять 60-80 дБ.When B = 10 ⁴

While the dynamic range of signals in a communication system with mobile subscribers can be 60-80 dB.

 In the inventive device at the input of the receiver, not included in synchronism with its subscriber station or entered in synchronism, but having a received signal level below the acceptable value (i.e., a receiver receiving a signal from a remote subscriber), powerful structural interference caused by nearby subscribers is compensated.

 The use of compensation provides additional noise reduction by (20-40) dB. That is, for the considered example, the degree of suppression of one structural interference is for the inventive device (50-70) dB, which is much more than for the prototype (30 dB).

Claims (1)

 The receiving equipment of the base station of the communication system with code division multiplexing, which contains serially connected control unit and the first switch, as well as N identical rulers, each of which contains serially connected receiver and demodulator, serially connected modulator and amplifier, characterized in that an adder matching the device and N second delay elements, and the first delay element, the subtractor and the second switch, as well as the synchronous a no-phase filter, while the output of the second switch of each line is connected to the input of the receiver of the corresponding line, the output of the demodulator of each line is connected to the input of the modulator of the corresponding line and is one of the N outputs of the device, the output of the amplifier of each line is connected to one of the N inputs of the first switch, N outputs of which through the corresponding N second delay elements are connected to the corresponding N inputs of the adder, N outputs of which are connected to the reference inputs of the synchronous-phase filters of the corresponding line, the output of the synchronous-phase filter of each of the N lines connected to the other input of the subtractor of the corresponding line, and the signal input of the synchronous-phase filter of each line connected to the output of the first delay element of the corresponding line, the input of which is connected to the second input of the second switch of the corresponding line and with one of the N outputs of the matching device, moreover, one of the outputs of the receiver of each of the N lines is connected to the corresponding input of the control unit, and the other output of the receiver of each line and connected to the corresponding input of the control unit and the modulator of the corresponding line, and the output of the control unit is connected to the corresponding input of the second switch of the corresponding line.

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