NO178517B - Telecommunication system and method of duplex communication - Google Patents

Description

The present invention relates to a telecommunications system and a method for duplex communication between a primary station and one or more secondary stations over one of a plurality of available frequencies.

In general, current telephone systems increasingly use wireless technology for long-distance calls and in some cases have begun to use digital technology. However, no system in general use today has been able to provide effective wireless digital technology for local calls to and from individual subscribers. Such technology has been discussed in various previous patents jointly owned by the applicant of the present application, see for example US patent no. 4,644,561 (February 17, 1987) and US patent no. 4,675,863 (June 23, 1987). The technology disclosed in these patents provides base stations in communication with both a remote switching center and a plurality of subscriber stations using digital wireless time division circuits where there are repeated sequential slot positions in a transmit channel's bit stream, each slot being associated with a particular subscriber.

Base stations used in the above-mentioned time-sharing system are relatively complicated and expensive, but economically feasible for a large system serving a large number of subscribers. However, for relatively small systems serving a relatively small number of subscribers, it may be economically infeasible. In addition, such a system uses a pair of frequencies, one for transmission and one for reception, and considering the limited amount of channels available in the spectrum, it would be very advantageous if only one frequency could be effectively used.

It is therefore the purpose of the present invention to provide what can be termed a simulated or emulated base station and which can effectively replace a real base station in certain situations, as well as a system which can be used for several subscribers, but which can only be operated on a single frequency.

The characteristic features of the invention appear from the attached patent claims, as well as from the subsequent description with reference to the attached drawings. Fig. 1 is a block diagram showing a total system comprising the present invention. Fig. 2 is a schematic illustration of the ECC waveform used in the standard base station. Fig. 3 is a schematic illustration of the ECC waveform used in the present invention. Fig. 4 is a schematic illustration showing the positive edges of the amplitude of the received signal used in rough synchronization according to the present invention. Fig. 5 is a block diagram of the circuit for achieving coarse synchronization according to the present invention. Fig. 6 is a block diagram of the received AGC circuit used in the present invention. Fig. 7 is a block diagram showing the frequency acquisition circuit used in the present invention. Fig. 8 is a schematic illustration of a wireless telephone system configuration according to the present invention. Fig. 9 is a schematic illustration corresponding to fig. 8, but which shows a dual subscriber system. Fig. 10 is a schematic illustration of the frame format for the dual subscriber system in fig. 9. Fig. 11 is a schematic illustration of the frame format for a majority of dual subscriber systems. Fig. 12 is a schematic illustration of a system incorporating the present invention which is used for monitoring one or more functions. Fig. 13 is a schematic illustration of an amplifier system which is covered by the present invention. Fig. 14 is a schematic illustration of a system which is covered by the present invention and makes use of several amplifiers. Fig. 15 is a schematic illustration of a system covered by the present invention, where a single amplifier is used to drive a majority of other amplifiers and subscriber units.

The total internal operation of the system, generally denoted by 10, is shown in block diagram form in fig. 1. In this system, during a telephone conversation, a person speaks into the telephone 12 and the speech signal is sent to the local telephone interface unit 14. The signal is digitized by the encoder/decoder KODEK 16 and the resulting digital data stream is then fed to the speech processor 18 which compresses the speech data to a lower data rate. The compressed data is then fed to modem 20 via line 22 and double-throw switch 24, the modem acting to convert the data stream into a spectrally effective analog signal. This analogue signal is fed to the radio 26 via line 28. The radio converts the signal into a radio frequency (RF) signal and then sends this RF signal via the antenna 30.

In the intervals between transmissions of the RF signals, the device is adapted to receive RF signals from a subscriber unit. The radio 26 downconverts each of these RF signals into an IF (intermediate frequency) signal and feeds this IF signal to the modem 20 via line 32. The modem 20 demodulates the IF signal to form a digital signal which is then fed to the speech processor via switch 24 and line 36. The speech processor then acts to expand the signal into a digitized speech signal and this digitized signal is then fed into the CODEC 16 which outputs an analogue speech signal to the telephone 12 via the telephone interface 14.

The data transmission mode is similar to that described above, except that the telephone is replaced by a data terminal or computer 38 and the telephone, said CODEC and speech processor are bypassed by means of the alternating position of the switch 24 which is then connected to the terminal 38 by means of lines 40 and 42.

The modem 20 and the radio 26 are both connected to a control unit 44. The control unit 44 is initially set to a predetermined gate, modulation and training mode for the modem and to a predetermined RF frequency and power level for the radio. However, these parameters can be adjusted by means of the subscriber unit in the event that they are not adequate to provide satisfactory reception at the subscriber station.

In a system that uses a real base station, for example as the system described in said US patent 4,675,863, the transmitted waveform is divided into a plurality (ie 45) m.sec. frames. Each frame is in turn divided into four 11.25 m.sec. hatches. The base station transmits on all four slots to provide a 100$ duty cycle modulation waveform, with the sole exception of the radio control channel (RCC). The RCC hatch is somewhat shorter than ll.25m.sec. and this causes a small gap in the modulation at the beginning of each frame. This gap is known as an AM gap. A diagram of the waveform in the RCC channel in the real base station format is shown in fig. 2. In the system according to the present invention, however, there is no transmission of a 100% duty cycle waveform. Instead, there is a transmission of only one hatch per frame (a 25% duty cycle waveform), as shown in fig. 3. This modified frame format necessitates changes in coarse synchronization, automatic gain control (AGC) and frequency honing. These changes are indicated in the following description.

As the system of the present invention uses only a 25% duty cycle waveform, it monitors the amplitude of the received signal and searches for positive edges in the amplitude signal. these positive edges are shown in fig. 4. The subscriber unit adjusts its time frame management to align with the appearance of these positive edges.

The circuit for achieving the above type of coarse synchronization is shown in block diagram form in fig. 5, where the received signal is shown fed into an amplitude calculation device 50 which produces a computer amplitude signal which is then fed to a comparator 52 where it is compared with a predetermined threshold signal, thereby forming a digital signal (1 = signal present, 0 = no signal present). This signal is fed into an edge detector 54 which outputs a marker (strobe) to indicate the detection of a positive edge.

The 25$ duty cycle modulation requires a distinct type of receive AGC circuit that avoids tracking when no signal is present. A slow rise, fast fall AGC is therefore provided. This is shown in fig. 6 where the received signal is fed in. in an amplitude calculation device 56, which may take the form of a pre-programmed ROM, from which a resulting amplitude signal is fed into a comparator 58 where it is subtracted from a predetermined threshold value to form a difference signal. This difference signal is fed through one of two scaling multipliers, shown as 60 and

62, into a low-pass filter comprising an adder 64 and a delay means 66 which is connected through a loop 68. One or the other of the two multipliers is used in accordance with sign of the difference signal. If the difference signal is positive, the slow decrease in the AGC control signal will be realized. If the difference signal is negative, a rapid increase in the AGC control signal is realized. The output from the filter is the gain signal which is then fed to the gain control unit 44 which is shown in fig. 1.

As in the 25% duty cycle frame format it is not required to perform frequency acquisition during the off-time (75% zero time) and as the frame time control is not known at the time when frequency acquisition is performed, a modified form of frequency acquisition circuit has been provided, as in fig. 7. In this circuit, the received signal is fed into a Discrete Fourier Transform (DFT) calculation device 70 which outputs the higher band energy (energy in the frequency band above the center frequency, and the low band energy (energy in the frequency band below the center frequency). The high band energy output is subtracted from the low band energy output on the adder 72 and its output is fed to a mixer or multiplier 74. The received RF signal is also fed to a tear-off means 76 which tears away the sign of the signal (negative or positive), whereby only the signal's absolute level (amplitude) is determined. The torn-off signal is then fed to a filter 78 which smooths the signal by averaging it.The output from the filter 78 is fed, via amplifier 80, to multiplier 74.

The primary purpose of the circuit through 76, 78 and 80 is to prevent the effect of noise on the output signal, while enhancing the signal itself. In this respect, since noise generally has a small amplitude, it is effectively filtered out during the smoothing process. On the other hand, since the real signal generally has a relatively large amplitude, it is effectively enhanced by adding the smoothed or filtered signal to the mixer 74.

The scaled signal leaving the mixer 74 is balanced between the high and low energy frequencies, and this balanced signal, which is proportional to the short-term average amplitude of the received signal, is fed into a low-pass filter comprising an adder 82, and a delay means 84 which is looped at 86. The delay means 84 causes the output signal 88 of the VCXO controller to represent the output immediately preceding the output actually fed into the low-pass filter. The VCXO control is used to adjust the frequency of the main oscillator in the system.

After initial or rough synchronization has been performed, the system is in idle voice mode, but is fully set up for voice operation. If the phone at one or the other end is taken off-hook, the phone at the other end will ring until the ringing phone is answered or the initiating phone is placed "on the hook".

The calls are set up by a voice code word (VCW) at the beginning. of each speech slot, this code word indicating an "off-fork" condition on the initiating station. When this happens, the station, which acts as an emulated base station, will itself appear to go "off-fork" to the remote communication center (CO) in order to establish a connection with the remote communication center. The initiating subscriber station then proceeds to complete the call by dialing the desired number. When the initiating subscriber unit goes "on-forked", the emulated base station is then informed by said VCW and presents an "on-forked" appearance to the remote relay center.

When the emulated base station detects a ringing signal from the remote switching center, the subscriber unit is caused to ring using the corresponding VCW from the emulated base station. When the subscriber unit then goes "off-forked", the emulated base station is informed of this via the corresponding VCW and it then presents an "off-forked" appearance to the remote relay center.

The above type of wireless telephone system configuration is exemplified in FIG. 8 where the subscriber unit 90 is shown in wireless communication via antennas 92 and 94 with the emulated base station 96. The station 96 is in wireline communication via line 98 and interface 100 with the remote switching center.

The system described above can be used with a double subscriber solution as shown in fig. 9. In this system, each channel is capable of supporting two complete conversations without the necessity of using a duplexer. In this regard, a dual subscriber unit 102 is connected by wires 104 and 106 to a pair of subscriber telephone sets 108 and 110. The subscriber unit 102 is in wireless communication via antennas 112 and 114 with an emulated dual base station 116. The unit 116 is connected to the remote communication center using wirelines 118 and 120.

The two separate subscribers 108 and 110 use a time slot solution as discussed in previously mentioned US patent 4,675,863, where each subscriber is assigned a separate slot. The frame format for this solution is shown in fig. 10 where four slots are shown, numbered 1, 2, 3 and 4. The first two slots are used for the emulated base station and the last two are used for the subscribers.

A majority of dual subscriber systems can be operated on different channels without duplexers by synchronizing all the emulated base station transmissions. This is shown using the frame format in fig. 11 where channel 1 is shown above channel n (indicating any desired number of channels in between) is shown below. On each channel, the first two slots are for transmission and the last two are for reception.

An emulated base station can be used with a plurality of different subscribers, one at a time. With such a solution, for reception the subscribers will continuously monitor the transmissions in the radio control channels (RCC), which is described in more detail in the aforementioned US patent 4,675,863, until a specific subscriber is called by the emulated base station using the subscriber's identity number (SID). After receiving a call, the subscriber initiates a transmission back to the emulated base station using the synchronization process described above. To initiate a call, the subscriber sends on said RCC using the previously described synchronization process.

The present system can be used for monitoring one or more functions. In this regard, using a computer as a controlling/data logging device, a plurality of subscribers may be periodically called upon to report on some function, such as temperature, weather conditions, security, water/flood warning, low fuel warning, remote gas, electricity or water meter readings, etc. This is shown in fig. 12 where an emulated base station 122 is in wireless communication with a plurality of subscriber units which are respectively denoted by 124, 126 and 128. The unit 122 is in wireline communication with both a telephone 130 for voice communication and a computer or data terminal 132 for data input. Likewise, each subscriber unit is connected both with a respective telephone 134, 136 or 138 for voice communication and with a computer device, such as at 140, 142 or 144.

An important use of the present system is as an amplifier to extend the system's range. In this solution, the emulated base station can be used to overcome disturbing obstacles, such as mountains and the like. Fig. 13 illustrates this function, showing a subscriber unit 146 in wireless communication with an emulated base station 148 on top of a mountain. The unit 148 is also in wireless communication with a standard base station 150 which is connected to a remote dispatch center.

The relative simplicity and affordability of the emulated base station makes it very cost-effective as an amplifier unit. It can also be used as an amplifier to extend the long-range range of the system regardless of the presence or absence of obstacles. Using the timeslot solution, the amplifier unit without the use of any duplexers fits into the complete system, while remaining transparent to both the standard base station and the subscriber. It can of course be introduced between the subscriber and another emulated base station instead of a standard base station. This can be provided in several stages from one emulated base station to another, to greatly increase the system's range in a relatively inexpensive way. This is shown in fig. 14 where a number of amplifier units 152 are inserted between the subscriber 154 and the base station 156.

In addition to extending the range of the system, the amplifier unit serves to clean up the real base station signal via equalization before retransmission to the subscriber. An amplifier can also be used in what can be called an amplifier star system to drive several amplifiers and/or subscribers. This is shown in fig. 15 where the one amplifier unit 158 is in wireless communication with auxiliary amplifiers 160 and 162, as well as with one or more subscribers, as at 164. The auxiliary amplifiers are themselves in wireless communication with subscribers, as shown at 166, 168, 170, 172 and 174 as well as with other auxiliary amplifiers, such as at 176. Any of the auxiliary amplifiers, such as amplifiers 162, may be used as the final amplifier in direct communication with the base station indicated at 178.

Several amplifiers can be placed in one place, on different channels and synchronized so that their transmissions and receptions occur simultaneously, thereby avoiding the use of duplexers. In such a configuration, the main amplifier is used to monitor the RCC channel for the base station and conveys the monitored information to the various subscribers via the emulated base station's RCC. In such a configuration, at call setup, the subscribers are each assigned an amplifier channel.

Claims (2)

1. Telecommunication system (10) for duplex communication between a primary station (122) and one or more secondary stations (124, 126, 128) over one of a plurality of available frequencies (Fig. 11), characterized in that: the primary station (122) has (i) means for sending synchronization information (20, 26, 44) which includes the allocation of time slots on a selected frequency (Fig. 10), at least two time slots (Fig. 10) for transmission from said primary station (122) and at least two time slots (Fig. 10) for reception by means of said primary station (122), (ii) means for transmitting a first signal for a first duplex communication on the selected frequency (20, 26, 44) in a first allocated transmission slot (Fig. 11), ( iii) means for transmitting a first signal for a second duplex communication on the selected frequency (20, 26, 44) in a second allocated time slot (Fig. 11), (iv) means for receiving a second signal for said first duplex communication ( 20, 26, 44) transmitted from a secondary station (124, 126, 128) on the selected frequency in a first allocated receiving slot (Fig. 11), (v) means for receiving a second signal for said second duplex communication (20, 26 , 44) sent from a secondary station (124, 126, 128) on the selected frequency in a second allocated reception slot (Fig. 11), and that the secondary stations (124, 126, 128) have: (i) means for receiving the synchronization information (20, 26, 44) from the primary station (122) and for identifying the selected frequency and assigned transmission and reception time slot (Fig. 11) for signals in a duplex communication with said primary station (122), (ii) means for receiving the signals for the duplex communication (20, 26, 44) from said primary station (122) on the selected frequency in the assigned primary station's transmission slot (fig . 11), and (iii) means for transmitting the signals for duplex communication (20, 26, 44) from said primary station (122) on the selected frequency in the assigned primary station's reception slot (Fig. 11). 2. Method for duplex communication between a primary station (122) and one or more secondary stations (124, 126, 128) over one of a plurality of available frequencies (Fig. 11), characterized by: (i) sending synchronization information from the primary station (122) to the secondary station (124, 126, 128) including the allocation of time slots on a selected frequency (Fig. 10), at least two time slots (Fig. 10) for transmission from said primary station (122) and at least two time slots (Fig. 10) for reception at using said primary station (122), (ii) transmitting from the primary station (122) a first signal for a first duplex communication on the selected frequency in a first allocated slot (fig. 11), (iii) transmitting from the primary station (122) a first signal for a second duplex communication on the selected frequency in a second allocated slot (Fig. 11), (iv) receiving by means of a first secondary station (124, 126, 128) said first signal for said first duplex communication in said first assigned slot (fig. 11); (v) receiving by means of a second secondary station (124, 126, 128) said first signal for said second duplex communication in said second allocated slot (Fig. 11); (vi) transmitting from the first secondary station (124, 126, 128) a second signal for said first duplex communication on the selected frequency in a third allocated slot (Fig. 10); (vii) transmitting from the second secondary station (124, 126, 128) a second signal for said second duplex communication on the selected frequency in a third allocated slot (Fig. 10); (viii) to receive by means of the primary station (122) said second signal for said first duplex communication in said third allocated slot (Fig. 10), and (ix) to receive by means of the primary station (122) said second signal for said second duplex communication in said fourth allocated reception hatch (fig. 10).