DE2242321A1 - FREQUENCY GENERATOR FOR VHF MULTI-CHANNEL RECEIVER - Google Patents

Description

Prior Art The invention relates to a frequency modulation VHF transceiver, that in simplex operation at receive and transmit frequencies work the same way are or differ from one another, and is particularly concerned with a frequency generator 9r such transceiver that generates: a) the superimposition frequency for conversion of the received signal from high frequency to intermediate frequency and b) the input frequency of the phase modulator of the transmitter.

In high frequency transmission between mobile stations or between mobile and fixed stations in most cases the frequency modulation and simplex operation with a configuration that is in the range from 30 to 174 NHz (VHF) works. The transmission and superimposition frequencies of the receiver are obtained from crystal controlled oscillators.

In general, the transmission frequency is determined by means of a multiplication get the frequency of the crystal controlled oscillator of the transmitter; thereby occurs also a frequency modulation. To ensure the stability of the frequency of the transmitter, phase modulation is used, which is equivalent to frequency modulation with is a boost of 6 dB per octave, and therefore causes the frequency multiplication also the multiplication of the modulation index.

The receiver is usually a heterodyne receiver with a Beating frequency obtained from a crystal oscillator, which in general a stage multiplier follows.

The two-way transceivers for the radio frequency transmissions mentioned above work with multiple utilizations (spacing of the high frequency channels) of 509 25 or 20 kHz.

Because the high frequency stage of the transmitter and the receiver have a bandwidth of about 1 MHz, two-way transmission can be carried out on any of the 20, 40 or 50 channels at a high frequency within the band of 1 MHz e corresponding to those mentioned above Multiple utilizations work without the coordination of the transmit and receive high frequencies will be changed.

In the case of a two-way radio frequency device, it is necessary in the Frequency generator a number of crystals for both the transmitter oscillator and the try to use the same number of channels for the local oscillator. These crystals are switched to the circuit of the oscillator according to the channel used. For example, to be able to work on 20 channels at high frequency, the Use of 40 crystals is absolutely necessary, namely 20 in the transmitter and 20 in the receiver.

in fact it is possible to use synthesizers that have an operation with a very high number of channels several hundred) by using a reference element in the form of a single crystal controlled oscillator.

But these are very expensive. Those of interest in the invention Radio frequency transmissions require operation on a reduced number of channels (e.g. twenty) for which the use of synthesizers from an economic point of view would mean no advantage.

The object of the invention is to provide a generator for simplex operation To create working transceivers that use it in an economical manner the same Crystals for both sending and receiving using the same properties of known transceivers are maintained by separate crystals in the transmitter and receiver.

In particular, the invention is concerned with a frequency generator for frequency modulation VHF transceivers operating in simplex mode on several high-frequency channels using the same crystals for both the emission and the Reception work, where the receiver is a heterodyne receiver and the transmitter is a phase modulation transmitter with a frequency multiplier.

Summary of the invention in a multi-channel transceiver with a Receiving part with a frequency converter whose output signal is in a relationship to the frequency difference one. received signal.

at a first input terminal and a second signal.

is at a second input terminal of the converter, and with a Transmitting part with a frequency multiplier contains a frequency generator according to the Invention: first oscillator devices which have a plurality of frequency sources included and effective to selectively transmit a signal at a first frequency of to generate one of the frequency sources, first frequency multiplier devices, the one input terminal coupled to the first oscillator means and an output terminal connected to the second input terminal of the frequency converter of the receiver part is connected, have and are operative to at their output terminal generate a signal whose frequency is a multiple of the frequency of the signal with a first frequency, second oscillator devices that are effective to generate a reference signal whose frequency is in a relationship to the difference frequency multiplied by a second multiplication factor, Devices having a first input terminal that is connected to the first oscillator devices is coupled, and having a second input terminal connected to the second oscillator means is coupled to generate a composite signal, and dividing means, the one input port coupled to the assembly means and an output terminal connected to the frequency multiplier of the transmitting part is coupled, have and are operative to convert the composite signal to a to divide predetermined factor.

Description of the drawing The invention is described below with reference to the drawing, in which Fig. 1 is a block diagram of a known one Frequency modulation transceiver, Fig. 2 is a block diagram of the frequency generator according to the invention and FIG. 3 shows another embodiment of an oscillator circuit, which is used in the embodiment of Fig. 2 is a detailed description of the drawing Background Art Referring to Fig. 1, there is the principle of operation of a frequency modulation transceiver shown with n high-frequency channels in the case of simplex operation. He can, in three Parts are shared: the receiver, the sender and the frequency generator. The receiver contains the series connection of the following blocks: Radio frequency (RF) amplifier 1, the input of which is connected to a contact of an antenna relay r, high frequency-intermediate frequency converter 2 with a second input R, which is connected to an output of the frequency generator is, intermediate frequency filter 3, intermediate frequency amplifier 4, limiter 5, discriminator 6, equalization circuit 7, audio frequency amplifier 8 and loudspeaker (or telephone receiver) 9. The transmitter contains a microphone 10, an audio frequency amplifier and level limiter 11, a phase modulator 12 with a further input T, which with the other output of the frequency generator is connected, an amplifier 13, a transmission frequency multiplier 14 with a multiplication factor nT, an amplifier 15 and a transmission output stage 16, the output of which is connected to the other contact of the antenna relay r. Of the The generator contains a local oscillator 17 which is connected to n crystals qH can be and its output via a frequency multiplier 18 with a multiplication factor nH to the second input R of the high-frequency intermediate frequency converter 2 of the receiver is connected, and a transmission oscillator 19, which can be switched to n crystals qT can and whose output is connected to the input T of the phase modulator 12.

The operation of this transceiver is known and is therefore not described here. It is only noted that the number of used Crystals is twice the number of operating channels of the transceiver.

Invention In Pig. 2 shows the frequency generator according to the invention. It replaces the frequency generator shown in the circuit diagram of FIG. 1 in dash-dotted lines Lines is enclosed, and contains a loop with a series connection of one Frequency converter 20 or a mixer, a band pass filter 21, a phase discriminator 22, a low-pass filter 23, a voltage-controlled Oscillator (VCO) 24, the output of which connects to the second input of the frequency converter 20 is connected, and a frequency divider 25, the input of which is connected to the output of the voltage-controlled oscillator 24 and its output to the input T of the phase modulator 12 in Fig. 1 are connected. The frequency converter also contains an oscillator 26, which can be switched to n crystals qH, its output being connected to both the second Input of the converter 20 as well as to the input of a frequency multiplier 27 is associated with a multiplication factor nH. The output of the multiplier is connected to the input R of the high-frequency intermediate frequency converter 2 in FIG and a crystal controlled oscillator 28 is connected to the second input of the phase discriminator 22 connected.

Taking into account the circuit in Fig. 1, the operation is based of the frequency generator of the invention in Fig. 2 is based on the following principle.

The frequency tqE of a crystal qll of the receiver's oscillator is given by fqH = (fRF - fIF) / nH (1), where fRF is the receiving frequency, fIF the intermediate frequency of the receiver and nH the multiplication factor of the frequency multiplier 18 are Equation (1) can also be written as fRF = nH fqH # fIF (2).

When the transmit and receive frequencies are the same, this is the input frequency fM of the phase modulator 12 of the transmitter given by fRF nT M nT (qH + fIF / nH) / (nE) (3) where nT is the multiplication. factor of the transmission frequency multiplier 14 is. This means that the input frequency 9 of the modulator by changing the Frequency of the oscillator. 26 of the receiver by fIF / nH and dividing the resulting Signal with nT / nH can be obtained. This division can be done from a circuit point of view only executed if nT / nH is an integer.

This process is illustrated by that shown in the block diagram of FIG Circuit according to the invention executed.

The frequencies of the two input signals of the phase discriminator 22 in the steady state are the same and, equal to the frequency fIF / nH, at which the crystal controlled oscillator 28 operates. In this state is the The output of the phase discriminator is a signal with constant amplitude, which after filtering out of the high frequency components through the filter 23 the voltage controlled oscillator 24 controls to cause it to oscillate at the frequency fqH # fIF / nH. This Value is the same as contained between dep brackets in equation (3).

The divider circuit 25 divides the through the voltage-controlled oscillator supplied prequens with nE and thus a frequency results that is equal to Is the frequency required by equation (3) at the exit of the platter 25. The frequency of the voltage controlled Oscillator 24 will also fed to the converter 20, in which it is mixed with the frequency fqH from the oscillator 26 to output a signal with a center frequency equal to fIF / nH. This signal is fed to the filter 21 to cut off all frequencies coming from the center frequency are different, whereby it in the phase discriminator 22 in phase is comparable.

Possible phase shifts and, accordingly, frequency shifts the two input signals of the rabbit discriminator 22 cause a positive one or a negative change in the voltage level at its output and therefore a corresponding frequency change. in the voltage controlled oscillator 24 which is about the connection to the converter 20 seeks to correct the phase error.

Accordingly, signals of very constant frequency can be made with the same Crystals can be obtained for both transmission and reception.

If the high frequency circuits of the transmitter and the receiver are the same Channel group are coordinated, it is possible in simplex mode to send and Reception channels that are different from each other, ru work.

This is done using another one shown in FIG Embodiment achieved, which is a circuit diagram similar to that in dashed lines Lines in Fig. 2 enclosed part replaced.

In this case, the oscillator 26 is by means of a receive-transmit relay 32 either to the common contact of switch 30 of the receiving channels or switched to the common contact of switch 31 of the transmission channels. Everyone who n crystals qH is with a different contact of the switch 30 and a different one Contact of switch 31 connected so that all n transmit frequencies for each receive frequency possible are.

When the mid-band frequencies of the transmit and receive channels are different are, the block diagram of FIG. 2 can nevertheless be used.

In such a case, however, if the difference between the center frequencies of the transmission and reception bands is the frequency of the oscillator 28 in Fig. 2 µm be changed.

Claims (4)

P a t e n t a n s p r ü c h e 1. Frequency generator of a multi-channel transceiver with a receiving part with a frequency converter whose output signal is related to the frequency difference a received signal at a first input terminal and, another signal at a second input connection of the converter and with a transmitter part a frequency multiplier, characterized by first oscillator means which comprise a plurality of frequency sources and are operative to selectively supply a signal to generate with a first frequency from one of the frequency sources, by first Frequency multiplier devices having an input terminal that is connected to the first Oscillator means is coupled, and an output terminal connected to the second Input terminal of the frequency converter of the receiving part is coupled, have and are operative to generate a signal at their output terminal, the frequency of which is a multiple of the frequency of the signal having a first frequency by second Oscillator means which are effective to generate a reference signal, its Frequency in relation to the difference frequency multiplied by a second multiplication factor stands, by devices having a first input terminal that is connected to the first Oscillator means is coupled, and to a second input terminal, the is coupled to the second oscillator means to a composite Signal to generate, and by dividing devices having an input terminal, the coupled with the assembling facilities is * and one Output terminal coupled to the frequency multiplier of the transmitter section, expand and are effective to the composite signal by a predetermined Share factor. 2. Frequency generator according to claim 1, characterized in that the first oscillator means a plurality of crystals, each of which is effective to generate a signal with a discrete frequency, an oscillator circuit, responsive to a signal from a selected source of the plurality of crystals is operative to generate the signal at a first frequency and switching means included that are coupled between the plurality of crystals and the oscillator circuit and are effective to selectively select one of the plurality of crystals with the oscillator circuit to pair. 3. Frequency generator according to claim 2, characterized in that the predetermined factor of the dividing means is the ratio of the first and the second multiplication factor is. 4. Frequency generator according to claim i, characterized in that the oscillator devices first and second crystals, which are respectively effective, to generate a signal at a discrete frequency, an oscillator circuit that an output terminal connected to the first frequency multiplier means and coupled to the assembly means, and an input port and is effective to be responsive to a signal of a discrete frequency generating the signal with a first frequency from one of the crystals, and switching devices Contain an output terminal that connects to the input terminal of the oscillator devices is coupled, and have first and second input terminals, which are respectively connected to the first and second crystal, the switching devices are effective to couple the first crystal to the oscillator circuit when the Transmitting part is effective, and to couple the second crystal with the oscillator 25U, when the receiving part is effective.