DE3233594A1 - Squelch method and arrangement for common-frequency radio networks - Google Patents

Abstract

Squelch method and arrangement for common-frequency radio networks, the radio receivers of which are blocked for the reception of unwanted transmitters. It is established whether a received RF signal falls into a narrow frequency window round the centre frequency of the receiver and the AF path is only opened when this criterion is met.

Description

Squelch method and arrangement for single-frequency radio networks

The invention relates to a squelch method according to the preamble of Claim 1 and an arrangement for performing this method.

in radio systems in which major radio interference is to be expected, A so-called tone squelch is often used to ensure that only the desired items are received To enable stations. The transmitters belonging to your own radio network are used for this purpose in addition to the useful signal, modulated with an identification tone (e.g. below 300 Hz, subsquelch). The squelch should only be opened if this tone is recognized by the other station will. This method cannot always be used in single-frequency radio networks.

The object of the invention is to provide a squelch method of the type mentioned at the beginning Specify the type that can be used in single-frequency radio networks.

The inventive method is described in claim 1, the arrangement according to the invention in claim 3. The further claims contain advantageous embodiments of the invention.

The invention is explained in more detail below with reference to the figures. Figures i to 3 show three advantageous embodiments of the invention Arrangement.

The principle of a tone squelch is the generation and recognition of a unique one Feature, tone. This is always required for an active squelch According to the invention, the feature is the highly constant carrier frequency of the single-frequency transmitter be.

In the case of single-frequency transmitters, a great deal of effort is made to ensure that the carrier frequency is adhered to to within 10 to 50 Hz. If you now set in the radio receiver determines whether a received signal falls within a narrow frequency window of 50 Hz around the receiver center frequency falls around in and only opens the squelch in this case, so you have one Squelch system with a security similar to that of a tone squelch. The selective one However, carrier frequency squelch is completely suitable for single waves.

FIG. 1 shows a first advantageous embodiment in a block diagram the invention. In the radio receiver with the receiving antenna A and the RF input stage (Pre-stage) the signal of the first IF is decoupled after the mixer Ml and fed to a narrow crystal filter QF. In order to achieve the required high accuracy of the To obtain IF, the first receiver superimposed LO must be connected to a common frequency standard FN be connected. This will usually already be available.

Behind the narrow quartz filter QF (bor100 Hz) is an HF detector circuit (Ausw) arranged with amplifier with which the squelch control signal is generated will. The IF amplifier thus has an additional signal processing path. In order to reliably recognize modulated external signals, this is detected in the detector Aus Signal integrated over a certain period of time before the downstream monostable Multivibrator MF (retriggerable monoflop) can be set and the switch S closes.

Modulated external signals whose carrier does not exactly match the expected frequency and which only happen to fall into the narrow frequency window for a few msec. are switched off by the integration and cannot trigger the monoflop. In single-frequency radio, the modulation for must accordingly at the beginning of a transmission a certain time (z. B. 50 msec) are suppressed so that the monoflop MF through the pure carrier can be set. Retriggering takes place in pauses in speech. The fall time of the monoflop is dimensioned accordingly (e.g. 5 sec).

FIG. 2 shows a second advantageous embodiment of the invention. The signal of the first IF is decoupled again and a second mixer M2 (the first superimposed LO must be connected to the single-frequency standard FN again be). In this mixer M2, the IF signal is normalized with one of the common frequency FN derived frequency (L02) mixed so that an exact receive frequency A frequency of 0 + 50 Hz is created.

With a steep low-pass filter TP (fgfiil50 Hz) the required selection is then implemented in order to start with a subsequent Evaluation circuit to generate the control voltage for the squelch S. For the detector Ausw and the monoflop MF is again the same as in the first embodiment Said.

FIG. 3 shows a third, particularly advantageous embodiment of Invention. From the receiver, whose first superimposed LO returns to the single-frequency standard FN must be connected, the first IF is decoupled again.

The decoupled signal is applied in parallel to two quartz filters, filters 1 and filter 2, the bandwidth of which is less than or equal to half the bandwidth of the filter determining the selection of the receiver and its center frequency so symmetrical to the IF center fm that both filters have one area without gaps cover their double individual bandwidth; both filters should be on the IF center overlap slightly. Each individual filter is followed by an amplifier and an RF detector circuit Selection

Both DC voltage signals obtained in this way become one Differential amplifier Diff supplied. Only if the difference is about 0, the received one Signal or

Spectrum is symmetrical to the nominal frequency, is over a Schmitt trigger trig a switching voltage for the squelch S released. These third embodiment of the invention is more complex than the previously described, but also recognizes with modulated signals whether they are very precisely at the setpoint frequency lie.

Interference spectra or signals from others, the respective single-frequency network third-party broadcasters are most likely not exactly on the expected Receiving frequency and are therefore determined by the method and the arrangement according to the invention safely suppressed.

Claims (6)

Claims 9 squelch method for single-frequency radio networks, their Radio receivers are blocked from receiving unwanted transmitters, thereby characterized in that it is determined in the radio receivers whether a received RF signal falls into a narrow frequency window around the receiver center frequency, and that the LF path of the radio receiver is only opened if this criterion is met is. 2. squelch method according to claim 1, characterized in that the frequency window with a width of e.g. B. + 50 Hz around the receiver center frequency is selected. 3. squelch arrangement for performing the method according to claim 1, characterized in that the local oscillator (LO) in the Fursk receivers the first IF stage is connected to a single frequency standard (FN), and that in a branch of the first IF signal in parallel to the IF amplifier and demodulator (Demod) a frequency evaluation circuit is arranged, which determines whether a received RF signal falls within a narrow frequency window around the receiving frequency falls and a switch (S) m NF-Weg s @@@@ ert. 4. Squelch arrangement according to claims ~ h ~ 3 -, - thereby gVekennseiGhw net, that the frequency evaluation circuit from the series connection of a narrow-band Quartz filter (QF), a detector with integrator (Ausw) and a retriggerable one Monoflops (MF) exists (FIG. 1). 5. squelch arrangement according to claim 3, characterized in that the Frequency evaluation circuit consists of the following elements connected in series: a second mixer (M2, L02), whose local oscillator (L02) is also on the common frequency standard (FN) is connected, a low-pass filter (TP), a detector with integrator (Ausw) and a retriggerable monoflop (MF) (FIG. 2). 6. squelch arrangement according to claim 3, characterized by the following Structure of the frequency evaluation circuit: - The first IF signal is always the input two filters (filter i, filter 2), whose bandwidth is less than or equal to half the bandwidth of the filter that determines the selection of the radio receiver and their center frequencies are so symmetrical to the IF center that both filters (Filter 1, Filter 2) completely cover an area of twice the individual bandwidth; - A detector with an integrator is connected to the outputs of the two filters (Ausw) whose output signals are fed to a differential amplifier (Diff), - A Schmitt trigger (Trigg) connects to the differential amplifier (FIG. 3).