RU2093964C1 - Device which searches and tracks synchronization signal for receiving satellite communication system - Google Patents

Abstract

FIELD: multiple-channel communication systems which use point-to-point connection. SUBSTANCE: device has four search channels, each of which has correlator, detector, integrator, circuit for automatic phase tuning, circuit for automatic frequency tuning, maximal signal detection unit, channel code generator, two random sequence generators, delay commutators and generator of control signals. EFFECT: increased functional capabilities, decreased search duration, increased signal- to-noise ratio in each channel, increased quality of signal filtration in each channel. 13 dwg

Description

 The invention relates to multi-channel communication systems, built on the principle of "each with each", and can be used in synchronization systems of such systems.

 The prior art synchronization device [1] consisting of the first and second multipliers, the first inputs of which are the input of the device, and their second inputs are connected respectively to the outputs of the carrier frequency generator, and the outputs of the multipliers are connected respectively to the inputs of the signal modulator, the clock input of which is connected to the output of the control unit and the control input of the threshold unit, the output of which is connected to the input of the control unit, the outputs of the signal modulator are connected respectively to the inputs of the integrators, the outputs of the odd integrators are connected respectively to the inputs of the first adder, and the outputs of the even integrators with the inputs of the second adder, the outputs of the first and second adder are connected through the corresponding quadrators to the corresponding inputs of the third adder, the output of which is connected to the input of the square root transformer, the first output of which is the first output of the device, and the second output is connected to the information input of the threshold block.

 There is also a device for synchronizing noise-like signals [2] which is additional to [1] and additionally contains a memory block connected in series, a comparison circuit, an additional adder and a frequency control unit, the output of which is connected to the control input of the carrier frequency generator, the control inputs of the comparison circuit and memory block are connected with the corresponding outputs of the threshold block, and the information input of the memory block is connected to the output of the control unit.

 These devices implement a parallel method of searching for a synchronization signal in frequency.

 From the prior art, the closest to the invention is a device for searching a pseudo-random signal 3, consisting of a first multiplier, the first input of which is the input of the device, and the second input is connected to the output of a controlled generator, and the output of the first multiplier is connected to the first inputs of the second, third and fourth switches the second inputs of which are connected to the output of the corresponding discharge of the shift register, the output of the second multiplier is connected to the inputs of the first and second amplifiers of intermediate frequency, the outputs of which, through the first and second detectors, respectively, are connected to the corresponding inputs of the first adder, the output of which through the amplifier is connected to the input of the controlled generator, the outputs of the third and fourth multipliers are connected respectively to the inputs of the third and fourth intermediate frequency amplifiers, the outputs of which are connected through the third and fourth detectors, respectively respectively, with the inputs of the second adder, the output of which is connected to the input of the low-pass filter, the output of which is connected to the input adjustable clock generator, the output of which is connected to the clock input of the shift register.

 This device implements a sequential method of searching for a synchronization signal in frequency.

 The disadvantage of a device that implements a parallel method for searching and tracking a synchronization signal is the redundancy of equipment, most of which is not used in synchronism mode after the search is completed.

 The disadvantage of a device that implements a consistent search method for the frequency of the synchronization signal is a rather lengthy search procedure.

 In addition, all known devices are not suitable for operation in satellite communication systems built on the principle of "each with each" and using different pseudorandom sequences for transmitting information and for transmitting synchronization signals.

 The technical problem that the device is aimed at is the development of a device for searching and tracking a synchronization signal in satellite communication systems with noise-like signals built on the principle of "each with each" and using different pseudorandom sequences for transmitting information signals and synchronization signals.

 The technical result from the use of the device is to expand the arsenal of technical means to solve this problem, reduce the duration of the frequency search, increase the signal-to-noise ratio in each of the search channels and improve the quality of signal filtering in each channel.

 This technical result is achieved by the fact that in the device for searching and tracking the synchronization signal in satellite communication systems (CCC) for receiving, comprising a first frequency converter, the first input of which is the information input of the device, and the second input is connected to the output of the controlled generator, a low-pass filter, four detectors, three correlators, a multiplier, an adder, a controlled clock and a phase-locked loop discriminator, the outputs of the first, second and third correlators are connected to the input respectively, of the first, second and third detectors, a high-frequency amplifier, a second frequency converter, a local oscillator, a fourth, fifth and sixth correlators, a fifth and sixth detectors, a resonant amplifier, a threshold element, five integrators, a maximum signal extraction unit, a channel code generator, are introduced, frequency discriminator, marker frequency generator, controlled signal generator, for a pseudo-random sequence generator, two delay switches, pulse frequency divider owl, key, control signal generator, reference frequency generator, sampling-storage unit, proportional-integrating filter, absolute value detector and voltage-frequency converter, the output of the first frequency converter through a high-frequency amplifier connected to the first input of the second frequency converter, the second input of which is connected to the output of the local oscillator, and the output of the second frequency converter is connected to the input of the low-pass filter, the output of which is connected to the first information inputs from the first sixth correlators, the outputs of the fourth and fifth correlators are connected to the inputs of the fourth and fifth detectors, respectively, the outputs of the first to fifth detectors are connected respectively to the information inputs of the first to fifth integrators, the outputs of which are connected respectively to the inputs of the maximum signal extraction unit, the outputs of which are connected respectively to the inputs of the channel code generator, a group of four outputs of which are connected respectively to the first fourth control inputs of the first and second delays, the fifth control inputs of which and the control input of the operating mode of the control signal generator are combined and connected to the output of the absence of the detection signal of the channel code generator, the fourth output of the group of outputs of which is also connected to the input of the passband setting of the proportional-integrating filter, the information input of which is connected to the output sampling-storage unit, the information input of which is connected to the output of the phase-locked loop discriminator, the first and second information the ion inputs of which are connected to the outputs of the second and third integrators, respectively, the reset inputs of all integrators are combined and connected to the "Reset" output of the shaper of control signals, the trigger input of which is the trigger input of the device, and the outputs "Information detection signal" and "End of search zone" of the shaper control signals are the corresponding outputs of the device, the output of the sixth correlator through a series-connected resonant amplifier and the sixth detector is connected to the information input a horn element, the input of the threshold setting of which is the input of the threshold setting of the device, and the output of the threshold element is the output of the marker signal of the device synchronization signal, the output of the marker frequency generator is connected to the first input of the multiplier, the output of which is connected to the second information input of the sixth correlator, the output of the fourth correlator is also connected to the input of the frequency discriminator, the output of which is connected to the input of the driver of the signal adjustment of the controlled generator, the outputs of which are connected respectively but with the inputs of the controlled generator, the output of the proportionally-integrating filter is connected to the input of the absolute value detector, the information output of which is connected to the input of the voltage-frequency converter, the output of which is connected to the first control input of the control clock generator, the second control input of which is connected to the sign output absolute value detector, and the clock input of the controlled clock is connected to the output of the reference frequency generator, the output of the controlled clock Ora is the output of the device’s clock pulses and is connected to the key information input and the first clock input of the control signal generator, the first clock output of which is connected to the key control input, the output of which is connected to the input of the pulse frequency divider and to the clock inputs of the first and second pseudorandom sequence generators, output the first pseudo-random sequence generator is connected to the first input of the adder and the information input of the first delay switch, the first is four whose outputs are connected to the second information inputs of the first to fourth correlators, the fourth output of the first delay switch is also connected to the second input of the multiplier, the output of the pulse frequency divider is connected to the second clock input of the control signal generator, the output of the second pseudo-random sequence generator is connected to the second input of the adder and information input of the second delay switch, the output of which is the output of the "Information sequence" of the device, and the adder output is connected to the second information input of the fifth correlator, the input signal recording of the storage sample unit and the read input of the proportional-integrating filter are combined and connected to the second clock output of the control signal generator.

 In FIG. 1 and FIG. 2 shows a diagram of the device, FIG. 3 an embodiment of a driver of control signals, in FIG. 4 an embodiment of a maximum signal extraction unit, in FIG. 5, an embodiment of a delay switch; FIG. 6 an embodiment of a channel code generator, FIG. 7 is an embodiment of a maximum signal detector; FIG. 8 is a diagram explaining the construction principle of the proportional-integrating filter; FIG. 9 an embodiment of a frequency discriminator; FIG. 10 shows an embodiment of a driver for adjusting signals of a controlled generator; FIG. 11 is a diagram of correlators; FIG. 12 the structure of the synchronization signal in the system, FIG. 13 a correspondence table of signals of a decoder of a maximum signal extraction unit, FIG. 14 table of correspondence of the signals of the decoder of the channel code generator.

 The device comprises an input 1, which is the first input of the first frequency converter 2, and a high-frequency amplifier 3, a second frequency converter 4, a low-pass filter 5, connected in series, the output of the first frequency converter 2 is connected to the input of the high-frequency amplifier 3, and the other input of the second converter 4 the frequency is connected to the output of the local oscillator 6. The output of the lowpass filter 5 is connected to the first information inputs of the first 7, second 8, third 9, fourth 10, fifth 11 and sixth 12 correlators, the output of the first correl Ora 7 through the first detector 13 is connected to the information input of the first integrator 14, the output of the second correlator 8 is connected through the second detector 15 to the information input of the second integrator 16, the output of the third correlator 9 through the third detector 17 is connected to the information input of the third integrator 18, the output of the fourth correlator 10 through the fourth detector 19 is connected to the information input of the fourth integrator 20, and the output of the fifth correlator 11 through the fifth detector 21 is connected to the information input of the fifth integrator 22, the outputs of the first 14th, second 16th, third 18th, fourth 20th and fifthth 22 integrators are connected respectively to the inputs of the maximum signal extraction unit 23, the outputs of which are connected respectively to the inputs of the channel code former 24, the first four outputs of which form a group of outputs 25, and output 26 is an output the absence of signal detection, the positions 27 and 28 indicate the outputs of the second 16 and third 18 integrators, respectively, and the installation inputs of the first 14, second 16, third 18, fourth 20 and fifth 22 integrators are combined and indicated by tion 29. The output of the correlator 12 through a sixth series-connected resonance amplifier 30 and the sixth detector 31 is connected to the data input of the threshold element, the reference input 33 which is the threshold corresponding input device and the output 34 of the threshold element 32 is an output device synchronization signal marker. Positions 35, 36, 37, 38 and 39 indicate the second information inputs of the first 7, second 8, third 9, fourth 10 and fifth 11 correlators, respectively. The first input of the multiplier 40 is connected to the output of the marker frequency generator 41, and the output of the multiplier 40 is connected to the second information input of the sixth correlator 12, the output of the fourth correlator 10 is connected to the input of the frequency discriminator, the output of which is connected to the input of the driver of the tuning signal of the controlled generator, the outputs of which are connected to the inputs of a controlled generator 44, the output of which is connected to the second input of the first frequency converter 2.

 The device also contains first 45 and second 46 pseudo-random sequence generators, a pulse frequency divider 47, a key 48, a reference frequency generator 49, the output of which is connected to a clock input of a controlled clock generator 50, the output of which is a clock output 51 and connected to the key information input, inputs 27 and 28 of the phase-locked loop discriminator 52 are connected respectively to the outputs of the second 16 and third 18 integrators, and the output of the discriminator 52 is connected to the information input of the storage-sampling unit 53, the output of which is connected to the information input of a proportional-integrating filter, the output of which is connected to the input of the absolute value detector 55, the information output of which is connected to the input of the voltage-frequency converter 56, the output of which is connected to the first information input of the controlled clock generator 50, the second information input which is connected to the sign output of the detector 55 of the absolute value.

 The device also contains a second 57 and a first 58 delay switch, the first four control inputs of which are connected to the group of outputs 25 of the channel code generator 24, and their fifth control inputs and the mode control input of the control signal generator 59 are combined and connected to the output 26 of the channel code generator 24, the fourth output of the group of 25 outputs of which is connected to the input of the installation of the proportional-integrating filter 54. The output 51 of the controlled clock 50 is also connected to the first clock input control signal generator, the trigger input of which is input 61, and the second clock input 60 is connected to the output of the pulse frequency divider 47, the first clock output 62 of the control signal generator 58 is connected to the control input of the key 48, the output of which is connected to the input of the pulse frequency divider 47 the inputs of the first 45 and second 46 pseudo-random sequence generators. The output "Information detection signal" is the output 63, and the output of the signal "End of the search zone" is the output 64 of the shaper 59 of the control signals, the output of which 65 is the second clock output and is connected to the input recording signal of the block 53 of the sample-storage and the input of zeroing proportionally integrating filter 54. The output of the first pseudo-random sequence generator 45 is connected to the first input of the adder 66 and the information input of the first delay switch 58, the first 35, second 36, third 37 and fourth 38 outputs of which are connected respectively, with the second information inputs of the first 7, second 8, third 9 and fourth 10 correlators, the output 38 is also connected to the second input of the multiplier 40. The output of the second pseudo-random sequence generator 46 is connected to the second input of the adder 66 and the information input of the second delay switch 57, output which is the output of the "Information sequence" of the device, and the output of the adder 66 is connected to the second information input of the fifth correlator 11.

 The driver 59 control signals (Fig. 3) contains a trigger 67 whose inverse output is connected to the inverse input of the element And 68 and the first input of the element And 69, the second input of which and the first direct input of the element And 68 are combined and are the first clock input 51 of the shaper, the output of the element And 69 is connected to the information input of the counter 70, the overflow output of which through the pulse shaper 71 is connected to the first input of the OR element 72, the output of which is connected to the zero input of the trigger 67, the single input of which is connected to the output of the form pulse generator 73 and a single input of the trigger 74, the direct output of which is the first clock output 62 of the driver, and the zero input of the trigger 74 is connected to the output of the And 68 element and the information input of the pulse counter 75, the overflow output of which is connected to the input of the pulse generator 73. The installation inputs of the pulse counters 70 and 75 are connected to the output of the pulse shaper 76, the first input of the OR element 77 and the single input of the trigger 78, the zero input of which is connected to the output of the OR element 79 and the second input of the OR element 72, and the direct output of the trigger 78 is connected to the second direct the input of the element And 68 and the third input of the element And 69, the fourth input of which and the third direct input of the element And 68 are combined and connected to the output of the element And 80, the input of the pulse shaper 76 and the input of the pulse shaper 81, the output of which is connected to the first at the input of the OR element 79, the second input of which is the start input 61 of the driver 59 of the control signals, and the third input of the OR element 79 is connected to the overflow output of the timer 82 and the zero input of the trigger 83, the direct output of which is connected to the first input of the And 80 element, the second input of which is the input 26 of the driver 59 of the control signals and connected to the inverse inputs of the elements AND 84, 85, 86, the output of the element AND 86 is connected to the input of the driver 87 of the pulses, the output of which is connected to the second input of the element OR 77, the output of which is connected to a new timer input 52, the operation enable input of which and the direct input of the And 86 element are connected to the inverse output of the trigger 83, the single input of which is connected to the output of the And 88 element, which is the output 63 "Information detection signal" of the shaper 89 of the control signals, the second clock input 60 of the shaper 59 control signals is the input of the counter 89, the overflow output of which is connected to the input of the pulse generator 90 and the input of the counter 91 pulses, the overflow output of which is the output 64 "End of the search zone" For 59 control signals, the output of the pulse shaper 90 is the reset output 29 and is connected to the direct input of the AND element 84, the output of which is the second clock output 65 and is connected to the first input of the And element 88 and the input of the delay element 92, the output of which is connected to the direct input of the element And 85, the output of which is connected to the second input of the And 88 element and the input of the delay element 93, the output of which is connected to the third input of the And 88 element.

 Block 23 extraction of the maximum signal (Fig. 4) contains a comparison circuit 94, the first input of which, the information input of the key 95 and the information input of the key 96 is the first input of the block, the second input of which is the second input of the comparison circuit 94, the information input of the key 97 and the information input key 98, the third input of the block is the first input of the comparison circuit 99, the information input of the key 100 and the information input of the key 101, the fourth input of the block is the second input of the comparison circuit 99, the information input of the key 102 and the information input key and 108, the fifth input of the block is the information input of the key 104 and the first input of the comparison circuit 105, the output of the "larger" comparison circuit 94 is connected to the control input of the key 95, the output of which is connected to the first input of the OR element 105, the second input of which is connected to the output of the key 97 whose control input is connected to an output “less than or equal to” the comparison circuit 94, the output “greater” of the comparison circuit 99 is connected to the control input of the key 100, the output of which is connected to the first input of the OR element 106, the second input of which is connected to the output of the key 102, the control in One of which is connected to the output "less than or equal to" the comparison circuit 99, the output of the OR element 105 is connected to the first input of the comparison circuit 107 and the information input of the key 108, and the output of the OR element 106 is connected to the second input of the comparison circuit 107 and the information input of the key 109, controlling the input of which is connected to the output "less than or equal to" the comparison circuit 107, the output of "greater than" which is connected to the control input of the key 108, the output of which is connected to the first input of the OR element 110, the second input of which is connected to the output of the key 109, the output of the OR element 110 is connected chen to the second input of the comparison circuit 105, a decoder 111, whose inputs are connected respectively to the outputs of the comparison circuits 94, 99, 105 and 107, the outputs of which are respectively controllable switch inputs 96, 98, 101, 103 and 104, key outputs are the outputs.

 Delay switches 57, 58 are made identically and contain (Fig. 5) series-connected delay elements 112, 113, 114, 115, 116 and 117, the information input of the switch is the input of the delay element 112 connected to the information input of the key 118 and the information input of the key 119 , the output of the delay element 112 is also connected to the information input of the key 120, and the output of the delay element 113 is connected to the information inputs of the keys 121 and 122, the output of the delay element 114 is connected to the information input of the key 123, and the output of the delay element 115 is connected to and to the formation inputs of the keys 124 and 125, the output of the delay element 116 is connected to the information input of the key 126, and the output of the delay element 117 is connected to the first input of the OR element 127 and the information input of the key 128, the first output of the switch is the output of the key 119, the second output of the switch is the combined output keys 118, 122 and 124, the third output of the switch are the combined outputs of the keys 121 and 125 and the output of the OR element 127, the fourth output of the switch are the combined outputs of the keys 120, 123, 126 and 128, the first control input of the switch and are the combined control inputs of the keys 118, 120 and 121, the second and third control inputs of the switch are, respectively, the first and second inputs of the OR element 129, the output of which is connected to the control input of the key 123 and the first inputs of the OR elements 130, 131, the outputs of which are connected to the control the inputs of the keys 122 and 125, respectively, the fourth control input of the switch are the combined control inputs of the keys 124 and 126 and the second input of the OR element 127, and the fifth control input of the switch are the combined control key moves 119 and 128 and the second inputs of the elements OR 130, 131.

 The channel code generator 24 (FIG. 6) comprises a decoder 132, triggers 133, 134, 135, 136 and 137, pulse shapers 138, 139, 140, 141 and 142. The first fifth inputs of the driver are the zero inputs of triggers 133-137, respectively. The first fifth inputs of the decoder 132 are connected respectively to the first to fifth inputs of the shaper, the first to fifth outputs of the decoder are connected to the inputs of the pulse shapers 138-142, the outputs of which are connected to the unit inputs of the triggers 133-136, the outputs of the triggers 133-136 form a group of outputs 25 , the output of the trigger 137 is the output 26 of the shaper.

 The absolute value detector can be made in the form (Fig. 7) of the peak detector 138 and the comparison circuit 139, the output of "greater than or equal to" which is the sign output of the detector, the information output of which is the output of the peak detector 138, the input of which and the first input of the comparison circuit are combined and is the input of the detector, and the second input of the comparison circuit is connected to the bus of zero potential.

The proportional-integrating filter 54 (Fig. 8) can be made in the form of an operational amplifier 140 with capacitors 141 and 142 in the feedback circuit and keys 144, 145, the information inputs of the keys are combined and connected to the input of the operational amplifier, the output of the key 143 is connected to the middle point of the capacitors, and the output of the key 144 is connected to the output of the operational amplifier. The control input of key 143 is input 25 ₄ , and the control input of key 144 is input 65 of the filter.

 The frequency discriminator 42 (Fig. 9) can be made in the form of a series-connected analog-digital converter 145, a frequency meter 146 and a code comparison circuit 147, another group of inputs of which is connected to the output of the sensor 148 of the nominal frequency value, the input of the discriminator is an analog-digital input converter 145, and the output is an output of "greater than or equal to" the code comparison circuit 147.

 The driver of the adjustment signal of the controlled generator 43 (Fig. 10) can be made in the form of an element HE 149, the output of which is connected to the input of the first element AND 150, the input of the driver is the input of the element HE 149 connected to the first input of the second element and 151, the second inputs of the elements And 150, 151 are connected to the output of the pulse generator 152, and the outputs of the driver are the outputs of the elements I.

 The correlators 7-12 (Fig. 11) are made in the form of a multiplier 152, the inputs of which are the inputs of the correlator, and the output of the multiplier is connected to the input of the bandpass filter 154, the output of which is the output of the correlator.

 The satellite communication system for which this device is intended is a multi-channel decentralized synchronous communication system in which each subscriber station (AC) can simultaneously provide communication with several subscribers in different directions and addresses (the principle of constructing "each with each").

 Moreover, all subscriber stations are of the same type. Each of them can work in the mode of the central station transmitting the clock signal, through which the remaining stations enter synchronism, and in the mode of the peripheral station, when it operates in the mode of receiving the clock signal of the central station and synchronizes its work according to the clock signal of the central station. The reception mode of the clock signal is the subject of consideration in this invention.

 The structure of the clock signal that is transmitted in the service channel is shown in FIG. 12.

The supercycle of the synchronization signal is 8s (T _sc = 8s) and is divided into 32 frames, each of which has a duration of T _frames = 250 ms. Each frame is divided into 15 cycles, duration T _c = 16, (6) ms. It, in turn, consists of five time-frequency intervals (positions), duration T _int = 3, (3) ms.

 In the service frequency channel, the clock signals of the central (DS) peripheral (PS) station, the busy signals of the information-frequency channels and service signals for organizing communication between the stations are transmitted.

 The content of any cycle, with the exception of the first, is the same.

1. In the 1st cycle of the first frame is transmitted:
in the first time interval, a super-cycle marker representing a meander with a frequency of 14.4 kHz and a marker duration of 3.3 ms;
at the second and third time intervals, circular information;
at the fourth and fifth time intervals, signals of employment of the time-frequency positions in the information-frequency channel.

2. In the first cycle of any frame, except the first, it is transmitted:
on the first three time-frequency intervals, circular information;
at the fourth and fifth time-frequency positions, employment signals of the time-frequency positions in the information-frequency channel.

3. In all cycles, except the first, is transmitted:
on the first time interval, the synchronization signal of the CA transmission;
at the second and third time intervals, signals of communication between subscribers (ringing signal);
on the fourth and fifth time intervals, the employment signals of the time-frequency positions in the information-frequency channel 7.

 Video signals in the service frequency channel (SCH) are Walsh functions that form the space of orthogonal signals. The Walsh function repetition rate (clock frequency) is 57.6 kHz. Video signals are multiplied with a cyclic pseudo-random sequence (DSP). Each DSP cycle consists of 1024 elements, following with a frequency of 921.6 kHz. The resulting signal is fed to the phase modulator.

Three types of memory bandwidths are used in SCH:
1. The sync sequence of the CA (SP CA). After multiplying the SP of the DS and the Walsh function N 1 (direct current), the clock generates the SS of the SS _ds , which is transmitted to all stations in the network. It is transmitted continuously by the central station, except for those time intervals where the CA transmits circular information, or ringing signals, or busy signals. Whenever a station is operating in DS mode, the same clock signal SS _{DS is generated} .

2. The sync sequence of the CA (SC PS). It is used to generate the CC _cs clock signal, which peripheral stations enter into synchronism for transmission. The sync signals CC _ps are transmitted at the first time intervals of the cycles.

 3. Informational SRP. After multiplying the information pseudorandom sequence with the information signal of any station, an information radio signal is generated, which each station of the network can receive and process, since the information sequence for all stations is the same.

 The information pseudo-random sequence is also multiplied with signals of circular information, with ringing signals and signals of busy time-frequency intervals.

Each subscriber station in the SCC is assigned a specific time interval for transmitting CC _ps .

 The principle of operation of the device is as follows.

 Synchronization signal The central station synchronization sequence (SP CS) is an almost continuous pseudorandom sequence with a period of 1.1 ms, a clock frequency of 921.6 kHz, and a number of elements of 1024. Every 8 s for 3.3 ms, a meander frequency of 14.4 is superimposed on the signal kHz, forming a supercycle marker.

 The task of the device is to ensure that when the subscriber station operates as a peripheral (reception mode), it ensures reliable separation of the clock signal of the central station and provides addition after it in frequency and delay, to develop a supercycle marker and other signals to control the station.

 A feature of the search for a noise-like signal is that the region of the body of uncertainty in the time-frequency space is small. Therefore, the signal can be detected at sufficiently close values of the frequency of the reference signals with the correlation detection method. It should also be borne in mind that in satellite communications systems, the frequency and delay of the signal changes slowly. Therefore, a sequentially-parallel detection method is put into the device’s operation, the essence of which is as follows.

 The received signal is converted into a signal with a low intermediate frequency (28.8 kHz) and fed to the multiplier, to the other input of which a reference signal is supplied with the same SRP as the received one. As a result of multiplication, when the signals coincide in time, the manipulation is removed, and a monochromatic signal is allocated by a narrow-band filter. The filter band determines the integration time of the signal with a narrow-band filter. The amplitude of the signal at the correlator output depends on the degree of proximity on the time scale of the received and reference signals. Therefore, after detection and additional integration on an interval equal to the duration of four DSPs, the output signal is supplied to the threshold device. To speed up the search, the device uses four parallel working channels, characterized in that in each of them the reference memory bandwidth is delayed by one clock in relation to the reference memory bandwidth in the previous detection channel. The excess in the channel of the received signal over the threshold level provides the basis for deciding on the presence of a signal. Such a construction of the detection channel with two integration steps eliminates the need to isolate the carrier oscillation accurate to the phase, which is very difficult to implement.

 The threshold level is formed in an additional fifth channel. It differs from others in that a logical mixture of SP and IN is used as a signal (reference sequence). The output effect of the channel is the average level of the noise component of the correlation convolution of the signals. Exceeding this level in any channel is a sign of a signal.

 Such an effect is achieved only if the input signal not only coincides in time with the reference signal, but also the frequency of the signal is close to the resonant frequency of the filter. Therefore, by restructuring the heterodyne, the maximum output effect can be achieved. Two-stage integration allows to resolve the contradiction between the requirement to ensure a large accumulation interval and the need to measure the frequency in a fairly wide frequency range. This allows you to measure the frequency at the output of the bandpass filter, compare the measurement results with the nominal value and adjust the local oscillator frequency to the desired value. Therefore, the search by frequency and delay are slightly dependent. The measurement process can also occur with a partial coincidence of the received and reference DSP.

 After a signal is detected in any of the four channels, the device switches to the auto-tracking mode in frequency and delay, at which the channels are switched so that the second and third channel signals are fed to the frequency-tuning loop, and the received signal is delayed in the tuning loop the signal of the fourth channel, delayed now between the second and third channel. In case of short-term disappearance of the received signal, the state of the synchronization system is memorized, and if the signal loss exceeds the established one, the search mode resumes. Frequency and phase tuning is possible only if a detected signal is present.

 The device operates as follows.

 In the initial state, the generators 44 and 50 generate signals with a nominal frequency, their tuning is absent. The clock generator 50 generates clock pulses, which are supplied to other blocks of the system, to the information input of the key 48 and to the clock input of the driver 59. After it is triggered by a signal from input 61, the generator uses a pulse counter and, simultaneously, a signal appears on the output 62, which closes the key 48. Clock pulses begin to arrive and clock inputs of the generators 45 and 46 begin to form pseudorandom sequences. The generator 45 generates the synchronization sequence of the PS PS, and the generator 46 information synchronization sequence of IP. They are logically summed in the adder 60, where the IP + SP sequence is formed, and also arrive at one of the delay switches 57, 58. In the delay search mode, at the outputs 35-38 four SP sync sequences are formed (one for each detection channel), characterized in that at each subsequent output the sync sequence is delayed by one clock cycle relative to the sequence at the previous output. The delay switch 57 uses only one output, the delay of which is equal to the signal delay at the fourth output 38 of the switch 58. After 1024 pulses are counted in the shaper 59, it prevents the next four clock pulses from the generator 50 from passing through the key 48. Thus, the delay varies phase of the generated sync sequences. The delay will change until a central station signal is detected or the set search time elapses. From the outputs of the switch 58 and the adder 66, the sync sequences are fed to the second inputs of one of the correlators 7-11.

 The signal from the output of the dump receiver is fed to the input of converter 2, with the help of which the signal is converted to a frequency of 70 ± 20 MHz, amplified by amplifier 3, and with the help of converter 4, a second conversion is carried out to a frequency of 28.8 kHz, and after filtering and amplification by filter 5, it is fed to correlators. Double conversion of the input signal frequency allows you to bring the intermediate frequency to a level an order of magnitude lower than the clock frequency, in the signal the SRP itself becomes the carrier, and the continuous envelope oscillation.

 The correlator, detector, and integrator connected in series form four channels for detecting the signal, and the channel for generating the reference voltage, in relation to which the decision is made to detect the signal, consists of a correlator 11, detector 21, and integrator 22. So far, the signal in any of the search channels does not exceed the reference voltage there is a signal at the fifth output of block 23 and at the output 26 of the driver 24.

 The manipulation of the input signal is removed in each of the detection channels using multipliers 153, and the bandpass filter 154 is the first channel integrator. The reduction in the intermediate frequency of the signal makes it possible to perform a bandpass filter with a very high Q factor; its bandwidth is comparable to the DSP duration, which provides good integrating properties of the filter and a sufficiently high signal to noise ratio at its output. The detectors 13, 15, 17, 19 and 21 are made in the form of linear amplitude detectors, therefore, the signal correlation function is reproduced at their output. Re-integration with the help of integrators allows you to extend the integration interval by the duration of several SRPs (in this case 4).

 If the reference signal generated in the fifth channel is exceeded in any detection channel, a single signal appears at the corresponding output of block 23 and the corresponding output 25 of the driver, and the signal at output 26 is reset. At the same time, in the switches 57 and 58, the PSP delay is switched, and the shaper 59 includes a phase-locked loop. The output switching in switches 57 and 58 is carried out according to the following rule.

 If the detection occurred in the first channel, then output 36 is connected to output 36, output 37 to output 36, and output 38 is connected to the output of delay element 112, i.e. the fourth channel becomes the largest delay between the second and third channels. The first channel is not used.

 If the detection occurred in the second or third channel, then their delay does not change, and the fourth output 38 is connected to the output of the delay element 114, i.e. again, the middle point is formed by the delay.

 If the detection occurred in the fourth channel, then in its place the third channel is connected, in the place of the third the second channel, and the fourth channel is again connected to the midpoint by the delay between the output of the delay element 116.

 When the signal disappears in the detection channels and the appearance of the signal at input 26, the original connection circuit of outputs 35-38 is automatically restored.

After switching, the process begins of fine-tuning the frequency of the clock generator 50 so that the maximum signal appears at the output of the fourth channel. At the beginning of the auto-tuning process, the PLL bandwidth is selected wider due to the open state of the key 143 in the filter 54. As soon as a signal appears at the output 25 _{4 of} block 24, the filter band decreases. To form a discriminatory characteristic, signals are taken from the output of the integrator 16 of the second channel and the output of the integrator 18 of the third channel. They enter the discriminator 52, made in the form of a subtraction unit, and the difference signal from it is fed to the storage sample unit. The signal from the clock output 65 of the shaper 59 is the record of the signal in block 53 and the zeroing of the filter 54, which after zeroing begins to work.

 The signal from the output of the filter 54 is fed to the detector 55, which determines the maximum (peak) value of the input signal and the sign of the signal by comparing it with zero potential. When the zero level is exceeded, a single signal is generated at the output of the comparison circuit 139, otherwise, a zero signal. These signals are input to the generator 50 to determine the direction of frequency tuning. The magnitude of the adjustment is determined by the frequency of the pulses from the output of the converter 56 into which the signal from the output of the detector 55 is converted. In this case, a mismatch of 0.5 τ is worked out until the maximum signal at the output of the fourth channel appears.

 The search for a signal by frequency is as follows.

The output signal of the correlator 10 is fed to the input of the frequency discriminator 42, in which, using an analog-to-digital converter 145, it is converted to digital form and fed to a frequency meter 146. Using the code comparison circuit 147, the measured and nominal frequency values are compared. Logic zero signal at the output of the comparison circuit 147 corresponds to the condition F _nom ≥F _edited, and a logic one signal to the condition F _nom ≅F _edited. Using the former 43, the logic zero signal passes through the AND element 150 to decrease the frequency of the controlled oscillator 44, and the logic unit signal through the AND 151 element increases the frequency value of the generator 44, which can be performed according to known frequency synthesizer circuits.

 The selection of the supercycle marker is carried out using the correlator 12, to the second input of which the result of multiplying the SRP from the input 38 and the signal of the generator 41 is supplied. The resonant amplifier 30 and the detector act as an integrator, whose signal when the threshold level set at input 33 is exceeded, in the threshold element 32 used in the future to form a supercycle marker.

 Separate blocks of the device operate as follows.

 In the maximum signal extraction unit 23 (Fig. 4), circuits 94, 99, 107 and 115 generate a single signal at the upper output (as shown in the drawing) if the signal at the upper input is larger than the signal at the lower input. Otherwise (the signal at the upper input is equal to or less than the signal at the lower input), a unit potential appears at the lower output of the comparison circuits. The decoder 111 analyzes the state of the comparison circuits and, depending on it, generates a signal at one of its outputs. The correspondence table of the signals at the input and output of the decoder is shown in FIG. 13. Thus, only one of the keys 96, 98, 101, 103, 104 will always be opened, and in the search mode, the key 104 will be opened.

 In the signal code generator 24 (Fig. 6), the input trigger corresponding to it is set to a state in which a single signal appears on its direct output, and the rest of the triggers are transferred using the encoder and pulse shapers to a state in which their direct outputs are set to zero potential. The correspondence table between the input and output signals of the encoder 132 is shown in FIG. 14. The pulse shapers generate a short pulse along the edge of the voltage drop at the corresponding output of the encoder in order to eliminate the ambiguity of the trigger state in the subsequent state when a signal appears on its other input.

 In the switches 57, 58 of the delay (Fig. 5), the delay in each of the elements is the same and is equal to 0.5 t where t is the duration of the bandwidth symbol (clock interval). In the search mode, the signal at input 26 closes the keys 119, 122, 125 and 128. In the first channel, the SRP delay is zero, in the second t in the third 2 t in the fourth 3 t When a signal appears on one of the inputs 25, the channels are switched over with the keys in accordance with with the above rule.

Shaper 58 control signals (Fig. 3) works as follows. driver 59 control signals solves the following tasks:
in the "search" mode, it prohibits the passage of four clock pulses through switch 47 to PSP generators with a period of 4T _isp ;
after the set search time has elapsed when the signal is not detected, it generates the signal "End of visibility zone";
when a signal is detected in one of the channels, it stops tuning of the delay and generates an internal clock enable signal that adjusts only when a signal is detected;
when repeating the detection signal three times, it generates an external signal "SOI" (information detection signal);
in case of a short-term loss of a signal after fixing the signal, the SDI prohibits frequency adjustment and turns on the standby timer. When the set waiting time has elapsed, an initial setting signal is generated, according to which the search mode resumes.

 In the initial state (Fig. 3), all counters are reset, the timer is not started, trigger 67 is set to a state in which there is a logic unit signal at its inverse output, which opens the And 69 element at the corresponding input and closes the And 68 element at the inverse input, trigger 78 is set to a state in which there is a logic zero signal at its direct output that closes the elements And 68, 69 at the corresponding inputs, trigger 83 is in a state in which there is a logical unit signal at its direct output that opens the element T and 80 on the corresponding input. The trigger 74 is set to a state in which a single signal is present on its inverse output and the key 47 is open.

 Since, in the absence of signal detection, a single potential is present at the output 26 of the driver 24, it enters through the And 80 elements and opens the And 68, 69 elements at the corresponding inputs.

 The search start signal from input 61 through the OR element 79 transfers the trigger 78 to the state in which a single signal from its direct output opens the And 68, 69 elements at the corresponding input. And through the OR element 72, the trigger 67 is transferred to the state in which the zero signal with its inverse output opens the element And 68 at the corresponding input and closes the And 69 element.

Clock pulses pass through the And 68 element to the counter 75, whose capacity is 4n _PSP , where n _{PSP is the} number of elements of the pseudo-random sequence. At the same time, the first clock pulse from the output of the And 68 element transfers the trigger 74 to a state in which a single signal from the direct output allows the clock pulses to pass to the pseudo-random sequence generators through key 48.

 The counter overflow signal 75, which is of a potential nature, enters the pulse shaper 73, which generates a short pulse along the signal edge, overturning the trigger 74, and the clock pulses do not pass through the key. At the same time, the trigger 67 is transferred to the state in which the signal And 69 opens with the signal from its inverse output and the And 68 element closes. Now the counter 70 works, the capacity of which is four. After the counter 70 is overflowed, the shaper 71 generates a short pulse: which, through the OR element 72, transfers the trigger 67 to the state in which the And 69 element is closed by the zero signal from its inverse output, and the And 68 element is opened. The first pulse passed through the element And 68, the trigger 74 is overturned and the clock pulses through the key again begin to flow to the OSS generators.

 There was a change in the delay of the pseudorandom sequences supplied to the correlators. This delay variation is carried out periodically until a signal is detected in one of the four channels.

 The counter 89, the capacity of which is four, counts the pulses "About PFP", corresponding to the beginning of the pseudo-random sequence. According to its overflow, the shaper 90 generates a short pulse, which, at the output 29, is fed to the reset of the integrators.

 When a signal is detected, the unit potential at the input 26 disappears, while the elements And 84, 85, 86 open at the inverse inputs, the voltage is removed from the input of the trigger 83 and, along the signal slice, the pulse shaper 81 generates a pulse, which sets the counters 70 and 75 to their initial state, and the And 68, 69 elements are closed by the trigger 78 at the corresponding input and the initial state of the timer 82 is confirmed. The search mode has ended and the delay adjustment mode has started. With this pulse, the output from the shaper 90 is fed to the sampling-storage unit and a proportionally-integrating filter through the And 84 element open through the inverse input.

 In case of loss (loss) of the signal, a single potential appears again at the input 26 of the driver, they are fed to the start input of the timer 82, the start of which is prohibited by the signal from the output of the trigger 83, and the And 84 element closes at the inverse input, terminating the auto-tuning mode. From the output of the And 80 element, the signal opens the And 68, 69 elements at the corresponding inputs, and a short pulse from the output of the shaper 81, generated along the edge of the signal at input 26, transfers the trigger 78 to the state through which the single signal appears on its direct output, and at trigger 67 a single signal also appears on the direct output. Search mode resumes.

 If the signal does not disappear during the delay in the auto-tuning process, then three pulses coincide in succession with the shaper 90 at the And 88 element. This is due to the fact that the delay in the delay elements 91, 92 is the same and equal to the duration of four SRPs. As a result of the coincidence at the output of AND element 88, a signal for detecting SDI information is generated. This signal is fed to the system output and at the same time overturns the trigger 83, which allows the start of the timer 82 and closes the AND element 80 at the corresponding input.

 Now, when the signal disappears for a short time and the potential appears at the input 26, the resumption of the search mode does not occur, since the And 80 element is closed and the trigger 78 will not be transferred to the state that opens the And 68, 69 elements. In this case, the timer 82 starts, which fulfills the set time delay and after working out the signal from the timer output through the open element OR 79 overturns the trigger 78 and resumes the search mode. If, before the timer ends, the signal reception resumes, then the driver 87 generates a pulse, which, through the OR element 77, sets the timer to its initial state.

 Thus, from the structure of the device and a description of its operation, it can be seen that the purpose is realized and the specified technical result is achieved.

A source of information
1. A device for synchronizing noise-like signals. Auth. testimonial. USSR N 576669, class H 04 J 3/06, 1975.

 2. A device for synchronizing noise-like signals. Auth. testimonial. USSR N 634473, class H 04 J 3/06, 1977.

 3. Interference immunity of radio systems with complex signals / G.I. Aces, V.A. Sivov, V.I. Prytkov et al. Ed. G.I. Tuzova. M. Radio and Communications, 1985, p. 129, fig. 4, 12 (the closest analogue).

Claims (1)

 A search and tracking device for a synchronization signal in satellite communication reception systems, comprising a first frequency converter, the first input of which is an information input of the device, the output of the first frequency converter is connected to the input of a high-frequency amplifier, and the second input is connected to the output of a controlled generator, a low-pass filter, two pseudo-random sequence generators and four signal detection channels, each of which includes a correlator, as well as a controlled clock generator, a disk a phase locked loop and a key, characterized in that a reference voltage generating channel is introduced into it, consisting of a correlator, a detector and an integrator connected in series, a synchronization marker extraction channel consisting of a correlator, a resonant amplifier and a threshold element connected in series, a second frequency converter, local oscillator, maximum signal extraction unit, channel code shaper, frequency discriminator, marker frequency generator, multiplier, signal shaper and adjustments of the controlled generator, adder, two delay switches, a pulse frequency divider, a control signal generator, a reference frequency generator, a sampling-storage unit, a proportionally integrated filter, an absolute value detector and a voltage-frequency converter, and series-connected signals are introduced into each signal detection channel a detector and an integrator, and the output of the correlator is connected to the input of the detector, and the output of the high-frequency amplifier is connected to the first input of the second frequency converter, the second input of which is connected to the output of the local oscillator, and the output of the second frequency converter is connected to the input of the low-pass filter, the output of which is connected to the first information inputs of the correlators of the signal detection channels, the channel for generating the reference voltage and the channel for allocating the synchronization marker, the outputs of the integrators of the signal detection channels and the output of the integrator the channel for forming the reference voltage is connected to the corresponding inputs of the maximum signal allocation unit, the outputs of which are connected to the corresponding the input inputs of the channel code generator, the four outputs of which are connected to the corresponding control inputs of the first and second delay switches, the fifth control inputs of which and the control input of the operating mode of the control signal generator are connected to the output of the absence of the detection signal of the channel code generator, the fourth output of which is also connected to the installation input the bandwidth of the proportional-integrating filter, the information input of which is connected to the output of the sample-storage unit, information whose input is connected to the output of the phase-locked loop discriminator, the first and second information inputs of which are connected to the outputs of the integrators of the second and third signal detection channels, the reset inputs of the integrators of the signal detection channels and the reference voltage generation channel are connected to the output "Reset" of the control signal generator, the trigger input of which is the trigger input of the device, and the outputs "Information detection signal" and "End of the search zone" are the corresponding you by the device’s moves, the input of the threshold threshold element setting of the synchronization marker allocation channel is the corresponding device input, and the threshold element output is the output of the device synchronization signal marker, the output of the marker frequency generator is connected to the first input of the multiplier, the output of which is connected to the second information input of the correlator of the synchronization marker allocation channel , the correlator output of the fourth signal detection channel is also connected to the input of the frequency discriminator, the output of which is is connected to the input of the driver of the signal for tuning the controlled generator, the outputs of which are connected to the corresponding inputs of the controlled generator, the output of the proportional-integrating filter is connected to the input of the absolute value detector, the information output of which is connected to the input of the voltage-frequency converter, the output of which is connected to the first control input of the controlled clock generator , the second control input of which is connected to the sign output of the absolute value detector, and the clock input of the control the clock generator is connected to the output of the reference frequency generator, the output of the controlled clock generator is the output of the device clock pulses and is connected to the key information input and the first clock input of the control signal generator, the first clock output of which is connected to the key control input, the output of which is connected to the input of the frequency divider pulses and with clock inputs of the first and second pseudo-random sequence generators, the output of the first pseudo-random sequence generator connected to the first input of the adder and the information input of the first delay switch, the four outputs of which are connected to the corresponding second information inputs of the correlators of the four signal detection channels, the fourth output of the first delay switch is also connected to the second input of the multiplier, the output of the pulse frequency divider is connected to the second clock input of the driver control signals, the output of the second pseudo-random sequence generator is connected to the second input of the adder and the information the input of the second delay switch, the output of which is the “Information sequence” output of the device, and the adder output is connected to the second information input of the correlator of the reference voltage generating channel, the signal recording input of the sample-storage unit and the read input of the proportional-integrating filter are connected to the second clock output of the signal conditioner management.

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