GB2300318A

GB2300318A - Improvements in or relating to transceivers

Info

Publication number: GB2300318A
Application number: GB8103989A
Authority: GB
Inventors: Christopher Keith Richardson
Original assignee: Plessey Co Ltd; Siemens Plessey Electronic Systems Ltd
Current assignee: Plessey Co Ltd; BAE Systems Defence Systems Ltd
Priority date: 1981-02-10
Filing date: 1981-02-10
Publication date: 1996-10-30
Anticipated expiration: 2001-02-10
Also published as: GB2300318B; GB8103989D0

Abstract

A transceiver comprises a pair of multiplicative mixers 1, 2 each having two input ports, aerial means 13 via which received signals are fed to one input port of each mixer of the pair, an oscillator 3 from which signals are fed to the aerial means 13 to provide carrier signals for transmission, a phase modulator 4 via which signals are fed from the oscillator to the other input ports of the mixers of the pair. A pair of low pass filters 6, 7 are fed one from each mixer. Phase quadrature means 5 are connected as shown, or in the aerial connection to mixer 1, and multiplier means 10 multiplies signals fed thereto from the low pass filters 6,7 and feeds via a further low pass filter 11 the phase modulator 4 thereby to control the phase of signals fed from the oscillator 3 to the mixers so that output signals corresponding to modulation carried by the received signals are produced at an output terminal of the transceiver fed from one of the low pass filters 6 of the said pair and so that output signals fed from the other low pass filter 7 of the pair tend to be nullified.

Description

IMPROVEMENTS IN OR RELATING TO TRANSCEIVERS This invention relates to transceivers and more particularly it relates to transceiver systems including a transponder adapted to receive radio frequency energy from the transceiver the energy received being modulated at the transponder and re-transmitted to the transceiver.

According to the present invention a transceiver comprises a pair of multiplicative mixers each having two input ports, aerial means via which received signals are fed to one input port of each mixer of the pair, an oscillator from which signals are fed to the aerial means to provide carrier signals for transmission, a phase modulator via which signals are fed from the oscillator to the other input ports of the mixers of the pair, a pair of low pass filters fed one from each mixer, phase quadrature means effective for producing a phase quadrature relationship between two of the signals fed from a common source to the mixers of the pair, multiplier means effective for multiplying signals fed thereto from the low pass filters and a further low pass filter via which a signal fram the multiplier means is fed back to the phase modulator thereby to control the phase of signals fed from the oscillator to the mixers so that output signals corresponding to modulation carried by the received signals are produced at an output terminal of the transceiver fed from one of the low pass filters of the said pair and so that output signals fed from the other low pass filter of the pair tend to be nullified.

The phase quadrature means may be arranged to be effective for producing a phase quadrature relationship between the signals fed to the mixers of the pair from the phase modulator.

The phase quadrature means may comprise a 900 phase shift device via which signals from the phase modulator are fed to one of the mixers of the pair.

The aerial means may comprise a transmitter aerial fed from the oscillator and a receiver aerial arranged to feed the mixers of the pair.

Alternatively a single transmit/receive aerial may be used arranged to feed the mixers and arranged to be fed from the oscillator via signal splitter means as described in our co-pending patent application No. 10360/76 for example.

The transceiver may form part of a transceiver system which includes a transponder adapted to receive signals received from the aerial means of the transceiver, the transponder including a modulator operative to modulate the received signals, the signals thus modulated being transmitted to the transceiver which is itself operative to provide an output signal on the said output terminal which corresponds to the modulation transmitted from the transponder.

The transponder may be passive and may comprise aerial means fed via a tuned circuit from a modulating transducer.

The modulating transducer may comprise a capacitor microphone which forms a part of the tuned circuit.

Alternatively the transducer may comprise a crystal microphone coupled to a varactor diode which forms a part of the tuned circuit and which is responsive to signals from the microphone for changing the reasonant frequency of the tune circuit thereby to modulate signals received by the transponder which thereafter are transmitted from the transponder.

The tuned circuit may comprise a transformer via which it is coupled to the aerial means of the transponder.

An embodiment of the invention will now be described by way of example with reference to the accompanying drawings in which: Figure 1 is a generally schematic block diagram of a transceiver system which includes a passive transponder and a transceiver; Figure 2 is a generally schematic circuit diagram of one form of passive transponder; and wherein Figure 3 is a generally schematic circuit diagram of an alternative form of passive transponder.

Referring now to Figure 1 the transceiver of the transceiver system comprises a pair of multiplicative mixers 1 and 2, fed with received signals from a receive aerial 3Q The mixers 1 and 2 are fed with local oscillator signals from an oscillator 3 via a phase modulator 4. The mixer 2 is fed directly from the phase modulator 4 whereas the mixer 1 is fed via a phase quadrature device 5. Output signals from the mixers are fed to a pair of low pass filters 6 and 7 which feed respectively amplifiers 8 and 9. Amplified signals from the low pass filters 6 and 7 are fed to a multiplicative mixer 10 and output signals from the multiplicative mixer 10 are fed back via a further low pass filter 11 to provide a control signal for the phase modulator 4.

In use of the transceiver signals from the oscillator 3 are amplified in an amplifier 12 and transmitted via a transmit aerial 13 to a passive transponder 14. Signals received by the passive transponder are locally modulated and re-transmitted from a transponder aerial 15. Thus it will be appreciated that signals transmitted from the aerial 13 are at the same frequency as carrier signals received at the aerial 3. The phase modulator 4 is operative to control the phase of the local oscillator signals fed from the oscillator 3 to the mixers 1 and 2, so that output signals are developed at an output terminal 16 of the transceiver, which correspond with the modulation transmitted from the aerial 15 of the passive transponder 14, the output terminal 16 being fed from the low pass filter 6 via the amplifier 8 and a further amplifier 17.

It can be shown that when a maximum output signal is developed on the output terminal 16 the signal fed to the mixer 10 from the amplifier 9 will tend to zero and a d.c. voltage will be produced on an output line 18 from the mixer 10 which is proportional to the phase difference between the signals fed to the mixer 10 and which has a sense indicative of the direction of any phase continuity. Thus the transceiver system operates in a similar manner to a suppressed carrier double side band system wherein cancellation of one side band occurs in the path which includes the low pass filter 7 and the amplifier 9 and wherein the received signal is maximised in the signal path which comprises the low pass filter 6 and the amplifier 8 feeding the output terminal 16.In effect the phase modulator 4 is controlled by means of the signal applied thereto via the line 18 so that the phase change introduced by the signal path between the transmit aerial 13 and the receive aerial 3 is compensated for whereby an undistorted signal is developed at the output terminal 16 which corresponds to the modulation imposed on the received signal and retransmitted by the passive transponder 14. Although most conveniently the transponder 14 may be passive, that is it may be energised by the signal power of the received signal, it may alternatively be an active transponder having its own local power supply.

One form of passive transponder is shown in Figure 2 and it comprises an aerial dipole 19 which is coupled to a tuned circuit 20 and wherein the tune circuit includes a capacitor microphone 21. It will be apparent to those skilled in the art that audio frequency signals received at the microphone 21 will tend to modulate signals received by the dipole 19 which are thereby re-transmitted.

Figure 3 shows an alternative type of passive transponder including a dipole 22 coupled to a tuned ciruit 23 which includes a varactor diode 24 shunted by a crystal microphone 25. In operation of the transponder output signals from the crystal microphone are effective to change the capacitance of the varactor diode 24 and thus the reasonant frequency of the tuned circuit, whereby modulated signals corresponding to the signals received by the microphone 25 are imposed on carrier frequencies received at the aerial 22 and effectively re-transmitted.

Various modifications may be made to the embodiments described without departing from the scope of the invention and for example the phase quadrature device may alternatively be incorporated between the aerial 3 and one of the mixers 1 or 2.

Additionally it is possible to provide a transceiver having a single transmit receive aerial which is coupled to the oscillator and the oscillator 3 and the mixers 1 and 2 via a suitable signal separation or splitter system.

It will be appreciated that by utilising a transceiver according to the present invention wherein direct conversion of received signal modulation is effected by means of the mixers which are fed in quadrature with a local oscillator signal phase locked to the received carrier, cancellation of the relatively large locally transmitted signal is effected which enables the much smaller retransmitted signal from the transponder to be received and demodulated.

Claims

LAIllS

1. A transceiver comprising a pair of multiplicative mixers each having two input ports, aerial means via which received signals are fed to one input port of each mixer of the pair, an oscillator from which signals are fed to the aerial means to provide carrier signals for transmission, a phase modulator via which signals are fed from the oscillator to the other input ports of the mixers of the pair, a pair of low pass filters fed one from each mixer, phase quadrature means effective for producing a phase quadrature relationship between two of the signals fed from a common source to the mixers of the pair, multiplier means effective for multiplying signals fed thereto from the low pass filters and a further low pass filter via which a signal from the multiplier means is fed back to the phase modulator thereby to control the phase of signals fed from the oscillator to the mixers so that output signals corresponding to modulation carried by the received signals are produced at an output terminal of the transceiver fed from one of the low pass filters of the said pair and so that output signals fed from the other low pass filter of the pair tend to be nullified.

2. A transceiver as claimed in claim 1 wherein the phase quadrature means is arranged to be effective for producing a phase quadrature relationship between the signals fed to the mixers of the pair fro the phase modulator.

3. A transceiver as claimed in claim 1 or claim 2 wherein the phase quadrature means comprises a 900 phase shift device via which signals from the phase modulator are fed to one of the mixers of the pair.

4. A transceiver as claimed in any preceding claim wherein the aerial means comprises a transmitter aerial fed from the oscillator and a receiver aerial arranged to feed the mixers of the pair.

5. A transceiver as claimed in claim 1, claim 2 or claim 3 wherein the aerial means is a single transmit/receive aerial arranged to feed the mixers and arranged to be fed from the oscillator via signal splitter means.

6. A transceiver as claimed in any preceding claim and forming part of a transceiver system which includes a transponder adapted to receive signals received from the aerial means of the transceiver, the transponder including a modulator operative to modulate the received signals, the signals thus modulated being transmitted to the transceiver which is itself operative to provide an output signal on the said output terminal which corresponds to the modulation transmitted from the transponder.

7. A transceiver as claimed in claim 6 wherein the transponder is passive and comprises aerial means fed via a tuned circuit from a modulating transducer.

8. A transceiver as claimed in claim 7 wherein the modulating transducer comprises a capacitor microphone which forms a part of the tuned circuit.

9. A transceiver as claimed in claim 7 wherein the transducer comprises a crystal microphone coupled to a varactor diode which forms a part of a tuned circuit and which is responsive to signals from the microphone for changing the reasonant frequency of the tuned circuit thereby to modulate signals received by the transponder which thereafter are transmitted from the transponder.

10. A transceiver system substantially as hereinbefore described with reference to the accompanying drawings.

10. A transceiver as claimed in claim 9 wherein the tuned circuit comprises a transformer via which it is coupled to the aerial means of the transponder.

11. A transceiver substantially as hereinbefore described with reference to the accompanying drawings.

Amendments to the claims have been filed as follows 1. A transceiver system, comprising a transceiver and a remotely located transponder which in use of the system is responsive to carrier signals transmitted from the transceiver for producing a modulated retransmission signal wherein the transceiver comprises a pair of multiplicative mixers each having two input ports, aerial means via which received retransmission signals are fed to one input port of each mixer of the pair, an oscillator which produces local oscillator signals for the mixers and from which signals are fed to the aerial means to provide the carrier signals for transmission, a phase modulator via which the local oscillator signals are fed from the oscillator to the other input ports of the mixers of the pair, a pair of low pass filters fed one from each mixer, phase quadrature means effective for producing a phase quadrature relationship between two of the signals fed from a common source to the mixers of the pair, multiplier means effective for multiplying signals fed thereto from the low pass filters and a further low pass filter via which a signal from the multiplier means is fed back to the phase modulator thereby to control the differential phase between the local oscillator signals fed from the oscillator to the mixers and the carrier signals for transmission so that output signals corresponding to the modulation carried by the received signals are produced at an output terminal of the transceiver fed from one of the low pass filters of the said pair and so that output signals fed from the other low pass filter of the pair tend to be nullified.

2. A transceiver system as claimed in claim 1 wherein the phase quadrature means is arranged to be effective for producing a phase quadrature relationship between the signals fed to the mixers of the pair from the phase modulator.

3. A transceiver system as claimed in claim 1 or claim 2 wherein the phase quadrature means comprises a 900 phase shift device via which signals from the phase modulator are fed to one of the mixers of the pair.

4. A transceiver system as claimed in any preceding claim wherein the aerial means comprises a transmitter aerial fed from the oscillator and a receiver aerial arranged to feed the mixers of the pair.

5. A transceiver system as claimed in claim 1, claim 2 or claim 3 wherein the aerial means is a single transmit/ receive aerial arranged to feed the mixers and arranged to be fed from the oscillator via signal splitter means.

6. A transceiver system as claimed in any preceding claim wherein the transponder is passive and comprises aerial means fed via a tuned circuit from a modulating transducer.

7. A transceiver system as claimed in claim 6 wherein the modulating transducer comprises a capacitor microphone which forms a part of the tuned circuit.

8. A transceiver system as claimed in claim 6 wherein the transducer comprises a crystal microphone coupled to a varactor diode which forms a part of a tuned circuit and which is responsive to signals from the microphone for changing the reasonant frequency of the tuned circuit thereby to modulate signals received by the transponder which thereafter are transmitted from the transponder.

9. A transceiver system as claimed in claim 8 wherein the tuned circuit comprises a transformer via which it is coupled to the aerial means of the tranrponder.