RU2042280C1 - System for transmission of digital telephone signals - Google Patents

Abstract

FIELD: telephone communication. SUBSTANCE: modules 2 of subscriber's concentration located at automatic telephone exchange 1 are connected with the aid of two cable lines to remote subscriber's modules 3 which are coupled through interface unit 6 of remote subscriber's modules and interface 8 to one end of cable television line 5. Digital telephone set 4 is linked to the other end of cable television line through N interfaces 9 connected in parallel each having own interface 7. EFFECT: provision for realization of requirements for electromagnetic compatibility of telephone communication lines inside buildings. 5 dwg

Description

 The invention relates to techniques for telephone communications and can be used to create multi-channel communications.

 Digital telephone systems are known (for example, UK application N 2219714, class H 04 M 3/00, 1989) comprising a central unit and several remote stations connected by bi-directional communication lines and connected to terminal subscriber units.

 A telephone system is also known (EPO application N 0386034, class H 04 Q 7/04, 1990), which includes many base stations connected to a central telephone exchange and many handsets, each group of which corresponds to one base station, since each base the station has a device for recognizing and receiving a call from the telephone exchange for handsets of the corresponding group, and each handset can establish radio communication with the corresponding base station.

 The prototype of the invention is a system for transmitting digital telephone signals of an electronic digital automatic telephone exchange EATS-CA.

 In the building of the telephone exchange are located subscriber concentration modules (IAC), each of which is connected by two cable lines to remote subscriber modules (UAM). Each UAM located in a residential building or office building, in turn, is connected by telephone pairs of wires with subscriber digital telephone sets (CTA). In the lines between IAC and UAM, temporary channel compaction is used. UAM carries out the reception of signals from the MAC, the allocation of the synchronization signal, the distribution of information signals at the outputs of the corresponding CTA. The semantic (informational) value of the transmitted sequences of zeros and ones is determined by the receiver (EATL or CTA) and does not affect the process of transmission of pulses in communication channels.

 The disadvantage of the prototype is the use of spatially separated wire lines for connecting UAM with each CTA, since they belong to open lines and have noticeable radiation losses, the spectrum of the emitted signals captures the entire broadcasting long-wave range and reaches the low-frequency edge of the medium-wave range due to the short pulse duration. In addition, a large consumption of copper.

 The purpose of the invention is to ensure compliance with the requirements for electromagnetic compatibility (elimination of radiation losses) in the UAM-CTA lines.

 In FIG. 1 shows a functional diagram of a system for transmitting digital telephone signals; in FIG. 2 is a functional diagram of a UAM interface unit with a TU-cable communication line; in FIG. 3 is a functional diagram of a unit for coupling a CTA with a TU-cable communication line; in FIG. 4 functional diagram of the buffer device; in FIG. 5 example of the implementation of matching devices.

 In FIG. 1 shows: 1 electronic automatic digital telephone exchange (PABX); 2 subscriber concentration module (IAC), 3 remote subscriber module (UAM), 4 digital telephone (CTA), 5 TU-cable communication line, 6 UAM interface with TU-cable communication line (BSUAM), 7 CTA interface unit with TU-cable communication line (BSSTA), 8 matching BSUAM device with TU-cable communication line, 9 matching device BSSTA with TU-cable communication line.

 In FIG. 2 shows: 10 buffer block, 11 pulse generator of the transmission channel "0" of the BSUAM transmitting part, 12 key of the transmission channel "0" of the transmitting part of the BSUAM, 13 block of time delay lines for generating frequency channels of the transmission channel "1" of the transmitting part of the BSUAM, 14 pulse shaper of the lines forming frequency transmission channels "1" of the BSUAM transmitting part, 15 element OR transmission channels "1" of the BSUAM transmitting part, 16 channel key of transmission channels "1" of the BSUAM transmitting part, 17 channel generators, 18 adder, 19 BSUAM receiving part receiving permission block, 20 time unit the delay time of the BSUAM receiving part, 21 adjustable amplifier of the BSUAM receiving signal lines, 22 mixer of the signal receiving lines, 23 low-pass filter of the signal receiving lines, 24 amplitude detector of the signal receiving lines, 25 threshold block of the signal receiving lines, 26 pulse shaper of the receiving unit buffer block 10, 27 switch.

 In FIG. 3 28 pulse shaper of the receiving channel "0" of the BSSTA receiving path, 29 pulse shaper of the receiving channel "1" of the BSSTA receiving path, 30 adjustable amplifier of the receiving channel "0" of the BSSTA receiving path, 31 mixer of the receiving channel "0" of the BSSTA receiving path, 32 filters low frequencies of the receiving channel “0” of the BSSTA receiving path, 33 amplitude detector of the receiving channel “0” of the BSSTA receiving path, 34 threshold block of the receiving channel “0”, 35 adjustable amplifier of the receiving channel “1” of the BSUTSTA receiving path, 36 receiving channel mixer “1 "BSSTA receiving path, 37 filter no of the frequencies of the reception channel "1" of the BSSTA reception path, 38 amplitude detector of the reception channel "1", 39 threshold block of the reception channel "1", 40 generator of the reception channel "0", 41 generator of the reception channel "1", 42 block of "0" "BSSTA receiving path, 43 BSSTA receiving path receiving permission block, 44 BSSTA receiving tract time delay unit, 45, 46 first and second BSSTA transmit path temporary delay blocks, 47, 48 first and second pulse train transmitters BSSTA, 49 transmitting path key BSSTA.

 In FIG. 4 50 buffer block duration selector, 51 buffer of transmission “1” to the CTA, 52 pulse shaper of the buffer block, 53 block of time delay of the buffer block, 54 buffer for receiving pulses from the CTA, 55 coincidence block.

 In the building of the EATL 1, MAK 2 are located, each of which is connected by two cable lines to the UAM 3. Transmission and reception of telephone signals from the UAM to the CTA and from the CTA to the UAM is provided by the TU cable network 5 of the collective antenna using the UAM interface units 6 and 7, respectively and CTA through its matching devices 8 and 9 with a TU-cable communication line.

Each interface unit UAM (see Fig. 2) BSUAM 3 consists of a receiving and transmitting parts. The transmitting part consists of the frequency channels of the transmission channel “0” and the transmission channels “1”, as well as the buffer unit 10 connected to the UAM. The transmission channel "0" consists of a pulse shaper 11 connected by an input to one of the outputs of the buffer unit 10, and by an output to a key 12, the second input of which is connected to the generator 17 of the channel "0" with a frequency f ₀ . Each of the frequency channels of transmission "1" contains an OR element 15, key 16, m lines of formation of frequency channels of transmission "1", where m is the number of temporary positions in each frequency channel of transmission "1". Each of these lines consists of a series-connected time delay unit 13 and a pulse shaper 14, the outputs of which are connected to m inputs of its element OR 15, the output of which is connected to the first input of the key 16 of its channel, the second input of which is connected to its channel generator 17 of the corresponding frequency and the output of each key of all channels is connected to the corresponding input of the adder 18. The inputs of the time delay unit 13 of the line are connected to the corresponding outputs of the buffer unit 10 "for transmission". The output of the adder 18 through the matching device 8 is connected to the TU-cable communication line.

 The receiving part of the BSUAM contains a reception permission block 19, a time delay block 20, the input of which is connected to one of the outputs of the buffer block 10, and the output to the input of the reception permission block 19, and as many signal reception lines from the CTA as the transmission channels “1” contain BSUAM transmitting part. Each line consists of series-connected adjustable amplifier 21, mixer 22, low-pass filter 23, amplitude detector 24, threshold block 25. The first inputs of the adjustable amplifiers 24 are connected to a matching device 8, the second inputs of these amplifiers 21 are connected to the output of the reception permission block 19, the second inputs of the mixers 22 are connected to their channel generator 17, the outputs of the threshold blocks 25 are connected to the inputs of the switch 27, controlled from the reception permission unit 19. The outputs of the switch 27 are connected to the corresponding the outputs of the buffer block 10 "to receive".

 The CTA interface unit (see Fig. 3) with the TU-cable communication line (BSCTA) 7 consists of the receiving and transmitting paths. The receiving path includes a receiving channel "0" and a receiving channel "1", each of which contains pulse shapers 28 and 29, respectively, connected by outputs to the CTA 4, and connected in series with an adjustable amplifier 30 and 35, a mixer 31 and 36, a low-pass filter 32 and 37, an amplitude detector 33 and 38, threshold blocks 34 and 39, respectively, while the second inputs of the mixers 31 and 36 are connected to the corresponding channel generators 40 and 41, the frequencies of which correspond to the frequencies of the generators 17 of the transmission channel “0” and the corresponding transmission channel “1 "transmitting parts of BSUAM to her. The BSSTA receiving path also includes a “0” 42 inhibit circuit, the first input of which is connected to the output of the threshold unit 39 of the receive channel “1”, and the output to the input of the pulse former 28 of the receive channel “0”, the receive permission block 43, the output of which is connected to the third input of the adjustable amplifier 35 of the reception channel "1", the time delay unit 44, the input of which is connected to the output of the threshold block 34 of the reception channel "0", and the output with the second input of the inhibit circuit "0" 42 and the input of the reception permission block 43. The output of the threshold block 39 of the transmission channel "1" is connected to the input form A transmission channel 29 pulses "1".

 The BSSTA transmission path includes two time delay blocks 45 and 46, two pulse shapers 47 and 48, and a key 49. Here, the CTA 4 output is connected to the first input of the first time delay block 45, the second input of which is connected to the output of the threshold block 39 of the receive channel "1 "the receiving path of BSSTA 7, and the output with the input of the second block of time delay 46, the output of which is connected to the input of the first pulse shaper 47, the output of which is connected to the first input of the key 49, the second input of which is connected to the generator 41 of the receiving channel" 1 "of the receiving path. The same output of the CTA 4 is connected to the input of the second pulse shaper 48, the output of which is connected to the second inputs of the adjustable amplifiers 30 and 35 of both receiving channels “0” and “1”. The output of the key 49 and the inputs of the adjustable amplifiers 30 and 35 of the reception channels "0" and "1" are connected through their matching device 9 to the TU-cable communication line.

 Transmission and reception of telephone signals are as follows.

 In the proposed system, pulses "0" are transmitted for all CTA 4 at the same frequency, pulses "1" are transmitted at n different frequencies and m different time positions in each frequency channel. Thus, each UAM 3 can communicate with M = m x n by the number of CTAs. The choice of specific values of m and n is determined by the requirements of manufacturability, energy consumption, the availability and cost of the element base and other additional requirements for the equipment. For this example, 11 frequency channels and 3 time positions were selected. For each CTA 4, the channel frequency and the temporal position of the pulse in this channel are strictly determined.

 UAM 3 transmits pulses with a duration of 2 μs and 4 μs to CTA 4, respectively, for transmitting "0" and "1". The CTA, in turn, transmits to UAM 3 pulses with a duration of 2 μs of negative polarity, which serve to transmit "1", and pulses from the CTA are generated with a delay of 2-3 μs. Pulses "0" CTA 4 does not transmit, UAM takes for "0" the absence of a pulse from the CTA. The pulses from the UAM to the CTA come with a clock frequency of 32 kHz, so that the time interval between them is 31.25 μs. After the pulse is emitted to the CTA 4, the UAM 3 goes to reception and waits for a response from the CTA 4 for only 6 μs. The rest of the time is allocated for signal processing inside the UAM: CTA propagation time in the communication line. The buffer unit 10 circumvents these difficulties.

 The work of BSUAM 6 on the transfer.

 The pulses from the UAM are sent to the buffer unit 10. If the pulse duration is 4 μs, then “1” is written to the transmission buffer 51, and “0” is written to the buffer 51 when a 2 μs pulse arrives. On the trailing edge of each pulse, the driver 52 forms a sequence of clock pulses used for temporary synchronization of BSSTA 7. Information from the CTA is recorded in the form of logical “0” or “1” in the receive buffer 54. With the delay necessary for the operation of the UAM depending on the state of the receive buffer 54 a pulse of 2 μs duration can be generated using a pulse shaper 26 and applied to the UAM.

Pulses "1" are shifted in each line of the formation of frequency channels by t _m using the time delay block 13. In this example, the number of time positions is m = 3, and the time shift of the pulses will be for the first n UAM channels t = 0 (in FIG. 2 there are no time delay devices in these channels), for the second n channels t = 3 μs, for the third n channels t = 6 μs. Next, the pulse shapers 14 generate pulses with a duration of 2.5 μs, which are transmitted through the OR circuit 15 to the switches 16, the second inputs of which receive signals from the corresponding channel generators 17. The radio pulses from the outputs of the keys 16 through the adder 18 are fed through a matching device 8 to the cable line communication. The synchronization pulses from the buffer block 10 start the pulse shaper 11 pulses of half-frame signals from the MAC, which control the key 12, the output of which is generated by the clock pulses of the frequency f ₀ .

 When the UAM is receiving radio pulses from BSSTA 7 through a matching device 9, a cable communication line 5, a matching device 8 are fed to the inputs of adjustable amplifiers 21 of the signal reception lines of the receiving part of the BSUAM 6. Control signals from the reception permission unit 19 are received at the second inputs of these amplifiers. In this case, the reception permission is received in m time intervals synchronously with the supply of control signals to the switch 27. After amplification, the radio pulses arrive at the mixers 22, to which the corresponding channel g 17. The generator of amplitude detectors 24 emit RF pulse envelope. Threshold blocks 25 are used to decide on the presence of a signal and convert the level of the input signals to the level of digital signals. From the outputs of the threshold blocks 25, the pulses are fed to the switch 27, made according to the scheme mPnH (m positions, n directions) and controlled by the reception permission unit 19. The switch 27 distributes the pulses along the inputs of the receive buffers 54 of the buffer block 10, these pulses are shifted at that time the time at which UAM is waiting for a response from the CTA. Pulses of 2 μs duration are generated depending on the state of the receive buffer 54 and are fed to the inputs of the UAM.

 Work BSSTA reception.

 The reception channel "0" starts the pulse shaper 28 with a duration of 2 μs, and the reception channel "1" starts the pulse shaper 28 with a duration of 4 μs. When the “0” and “1” pulses of the “0” and “1” pulses appear simultaneously at the inputs of the adjustable amplifiers 30 and 35, the “zero” block prohibits 42 “0” pulses are blocked, the resolution block 43 opens the “35” receive channel the adjustable amplifier 35 1 "at a strictly defined moment for receiving pulses, embedded in the time delay unit 44.

When transmitting from the CTA, the pulses are time-shifted in the first block of time delay 45, so as not to overlap the transmission cycle of the UAM to the DIA and if this channel is not at the zero time position (in this case, if there is a shift of 3 μs or 6 μs), is added and the time offset corresponding to the second channel a time delay device 46 BSTSTA transmission path 7. then pulse shaper 47 operates duration 2.5 ms, pulse generator that is modulated by a channel 41 corresponding to the frequency f _n to the second input key 49. on neous with the transmission pulse from CTA locked adjustable amplifiers 30 and 35 receive path BSTSTA the pulse duration of the pulse half-frame transmit path 48.

 Thus, the proposed system makes it possible to ensure the electromagnetic compatibility requirement as a communication line between the UAM and the CTA group of the cable network, and due to the distribution of pulses in the UAM CTA lines along n frequency channels and m time positions in each channel, the high quality of separation of these channel signals.

Claims (1)

 DIGITAL TELEPHONE SIGNALS TRANSMISSION SYSTEM containing wired communication lines, subscriber concentration modules (MAC), each of which is connected to remote subscriber modules (UAM) by two-cable communication lines, N digital telephone sets (CTA), characterized in that the UAM interface unit is introduced ( BS UAM), matching device (SU AM) N CTA interface units (BS CTA), N matching CTA devices (SU CTA), and wired communication lines are made in the form of a cable television line (TV cable lines), and the linear inputs of the UAM outputs are connected the corresponding outputs of the BS UAM, whose output through SUAM is connected to one end of the TV cable line, the other end of which is connected to the combined inputs of the SU CTA, the outputs of which through the corresponding BS CTA are connected to the corresponding CTA, each BS UAM consists of a buffer unit whose inputs the outputs of which are inputs - outputs of the BS UAM, and the first output of the buffer unit, which is the input of the zero transmission channel, is connected to the input of the pulse shaper of the zero transmission channel, the output of which is connected to the first input to yucha transmission channel "zero", the second input of which is connected to the generator of the zero "channel", n frequency transmission channels of the "unit", each of which consists of m frequency lines of the transmission channels of the "unit", where m is the number of temporary positions, each of which consists from series-connected time delay unit and pulse shaper of the “unit” transmission channel, n OR elements, the outputs of which are connected to the first inputs of the corresponding n keys of the “unit transmission” channels, the second inputs of which are connected to the corresponding channel genes and the frequency channels of the unit transmission channels by the inputs of the time delay blocks are connected to the corresponding m · n outputs of the “transmission” of the buffer block, and the outputs of the pulse transmitters of the unit transmission channel are connected to the corresponding one of the m inputs of the corresponding OR element, and the outputs of the transmission channel keys are “zero” "and" units "are connected to the inputs of the adder, the output of which is the output of the BS UAM, n reception lines, each of which consists of a series-connected adjustable amplifier, mixer, filter low-frequency detector, amplitude detector and threshold block, the output of which is connected to the corresponding input of the switch, the control inputs of which are connected to the corresponding outputs of the reception permission block, the control output of which is connected to the second inputs of the adjustable amplifiers, and the input of the reception permission block through the reception time delay block is connected to the first output of the buffer unit, the inputs of which "are received" are connected to the corresponding outputs of the switch, and the second inputs of the mixers are connected to the corresponding channel oscillators, and the combined inputs of the adjustable amplifiers are the input of the UAM BS for reception, with each CTA BS consisting of a receiving path and a transmitting path, and the receiving path contains a zero receiving channel and a unit channel, each of which contains a pulse shaper, a channel generator, as well as a series-connected adjustable amplifier, mixer, low-pass filter, amplitude detector and threshold block, the second inputs of the mixers connected to the corresponding channel generator Oram, a block of zero inhibit, a block of reception permission and a block of time delay, and the first input of the block of prohibition of “zero” is connected to the output of the threshold block of the reception channel “units” connected to the input of the pulse shaper of this channel, the output of which is combined with the output of the shaper and pulses the “zero” receiving channel is the output of the CTA BS, and the output of the “zero” receiving channel pulse shaper is connected to the output of the “zero” prohibition block, the second input of which is connected to the first output of the time delay block, the input of which is connected to the output m of the threshold block of the reception channel is “zero”, and the second output is connected to the input of the reception permission block, the output of which is connected to the control input of the adjustable amplifier of the reception channel of “unity”, the first input of which, as well as the first input of the adjustable amplifier of the reception channel of “zero” are corresponding the inputs of the BS CTA, while the transmitting path contains the first and second pulse shapers, the key and the first and second time delay blocks, the output of the first time delay block through the second time delay block and through the first The first pulse shaper is connected to the first input of the key, the second input of which is connected to the output of the channel generator of the reception channel of the unit, and the output of the key is combined with the input of the adjustable amplifier of the reception channel of the unit, the first input of the first block of the time delay of the transmission path being the output of the BS CTA and connected to the input of the second pulse former, the output of which is connected to the combined second inputs of the adjustable amplifiers of the channel, the receptions of "zero" and the reception channel of "unity", and the second input of the first block is temporary the delay of the transmitting path is connected to the first input of the block prohibition "zero".

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