KR800001091B1 - Transceiver squelch circuit - Google Patents

Abstract

In a squelch circuit(40) adapted for use in the receiver portion(10) of a transceiver having a switching means to select either the transmit or receive mode, the receiver includes the means for providing an AGC signal. The squelch circuit comprises hysteresis means(50) for unmuting the receiver at the first AGC threshold level and decaying means responsive to the switching means.

Description

Squelch Circuit of Wireless Transceiver

The accompanying drawings show a circuit according to the invention for use with a radio frequency transmitter.

TECHNICAL FIELD The present invention relates to the field of wireless communications technology, and in particular to squelch circuits that are made suitable for use in wireless transceivers.

Squelch circuits used in wireless receivers are well known in the communications art. The operation of the squelch circuit includes monitoring the level of the signal received and processed by the receiver and muting the receiver if the signal does not exceed a certain threshold level. As the squelch circuit operates, the user of the receiver is not subject to the unpleasant noise that appears when no information signal is received. Squelch circuits are commonly used in amplitude modulated receivers, particularly for two-way amplitude modulated radio transceivers.

A problem that has been eliminated in the squelch circuits used in conventional amplitude modulator receivers is that squelch often affects the fading of the signal. That is, a signal to be received strongly causes a fading phenomenon at that level sometimes by interference of the transmission medium. Regardless of whether the receiver is muted or not, if the threshold level of the squelch operation is set to the same level, the receiver will be inoperative during the fading period, thus disrupting communication to the receiver.

Moreover, the previous squelch circuits did not adequately act on the switching transients that occur when switching an amplitude modulated radio from the transmit mode to the receive mode. During and after the switching of the switch, the circuitry in the receiver may generate an unpleasant transient signal to the receiver when the receiver is not muted.

In short, the squelch horn according to the present invention has been adapted for use in the receiver portion of a wireless transceiver. The radio transceiver has a switch that can be selected as either the transmit mode or the receive mode. In the receiver part, an apparatus for providing an automatic gain control (AGC) signal is configured. The squelch circuit is configured with a hysteresis device that does not mute the receiver at the first AGC threshold level, but mutes the receiver at the second AGC threshold level. The squelch circuit also has a delay that responds to the radio transceiver switch so that the receiver is muted for a period of time after switching the radio transceiver from transmit mode to receive mode.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The figure shows a wireless transceiver comprising a receiver portion 10 and a transmitter portion 12. Receiver 10 and transmitter 12 are selectively coupled to antenna 14 by antenna switch 16.

The illustrated receiver 10 is an amplitude modulated receiver with a radio frequency amplifier 18 at its input. The radio frequency amplifying stage 18 is configured with a selection circuit for tuning to the originating station or channel for the receiver 10.

The output of the radio frequency amplifier 18 is applied to the mixer 20. The mixer 20 is also coupled with a local oscillator 22. The mixer 20 operates in the usual manner to convert the signal received from the radio frequency amplifier to an intermediate frequency. The intermediate frequency signal generated thereby is introduced into the intermediate frequency filter and the amplifier stage 24. The intermediate frequency filter and amplification stage 24 filters and amplifies the intermediate frequency to eliminate unnecessary signals. As a result, the filtered intermediate frequency signal is applied to any amplitude modulation detector 26 that demodulates the audio signal in the received radio frequency signal. This audio signal is amplified by the audio frequency amplifier 28 and then transmitted to the speaker 30 and converted into an audible sound at the same time.

The intermediate frequency filter and amplifier stage 24 includes a circuit for providing an automatic gain control (AGC) output signal to the AGC output terminal 32. This AGC signal represents the level of the signal received and processed by the receiver 10. In this particular embodiment of the present invention, the AGC signal generated at the IF output terminal 32 is inversely proportional to the received radio frequency level. That is, the generated AGC signal decreases relatively as the received frequency signal increases.

The AGC voltage at the AGC terminal 32 of the IF terminal 24 is fed back to the gain adjusting input terminal of the radio frequency amplifier 18 to adjust the gain of the radio frequency amplifier 18. Such AGC feedback is well known in the art and is used for the purpose of maintaining the RF stage 18 and then the linear motion mode.

The transmitter portion 12 comprises a microphone 33 which is fed to the transmitter 34 in an aired way. The transmitter generates an amplitude modulated radio frequency signal transmitted via the antenna 14. The microphone 33 is associated with a push to talk switch 36, which switches the DC bias power source B ⁺ according to its position to either the receiver 10 or the transmitter 34. It is switched to apply to the side.

The receiver portion 10 is shown with a squelch circuit 40 according to the invention combined. The input terminal of the squelch circuit 40 is a PNP transistor 42 that acts as an emitter follower. The AGC signal output from the intermediate frequency filter and the amplifier 24 is applied to the base of this transistor 42. As the level of the AGC signal changes, a change occurs in the emitter voltage of the transistor 42. The emitter of transistor 42 is coupled via the load resistor 44 to the B ⁺ output of the receiver supplied from the switch 36, which is also coupled to the input of the hysteresis circuit 50 via the coupling resistor 46. Combined. The input terminal of the hysteresis circuit 50 is the base of the NPN transistor 52, which is connected to the B ⁺ terminal of the receiver through the load resistors 54 and 56 connected in series. The emitter of the transistor 52 is a potentiometer 58. The potentiometer was connected to one end of the potentiometer to B ⁺ , the DC power supply of the receiver, and the other end to the reference point through a resistor (60). A shunt resistor 62 is connected across the resistance of the potentiometer 58, and the resistance value is selected to determine the resistance range of the potentiometer 58.

The output at the common connection point of the collector load resistors 54, 56 is applied to the base of the PNP transistor 70. The emitter resistor 72 of transistor 70 is coupled to the receiver B ⁺ output output from switch 36, and the feedback collector load resistor 74 of this transistor 70 is the base of hysteresis transistor 52. Connected to. The delay capacitor 76 is coupled between the base and the collector of the PNP transistor 70.

The output from the PNP transistor 70 is voltage divided by a pair of resistors 80 and 82 and then applied to the base of the output buffer transistor 84. This buffer transistor 84 is of the NPN type, whose emitter is connected to ground potential and its collector is connected to the output of detector 26.

The operation of the squelch circuit is as follows. The voltage applied to the base of transistor 42 is inversely proportional to the strength of the received RF signal. In order for the transistor 52 to energize, this voltage must be greater than or equal to the threshold voltage determined by the voltage between the base and emitter of the transistor 52 and the setting position of the potentiometer 58. For the strongly received RF signal, the base voltage of the transistor 52 is equal to or less than this threshold voltage, and the transistor 52 is brought into a non-energized state. As the transistor 52 is not energized, a base B ⁺ voltage is applied to the base of the transistor 70, so that the transistor 70 is also energized, thereby biasing the buffer transistor 84 to a non-energized state. When the transistor 84 is in the non-energized state, the output signal of the detector 26 is applied to the audio frequency amplifier 28 and the speaker 30 to operate without the receiver being muted. As the received RF signal decreases, the AGC signal increases inversely so that the base voltage of the transistor 52 becomes above the threshold voltage. As a result, the transistor 52 is saturated, and then the transistor 70 is also saturated. When the transistor 70 is in saturation, the buffer transistor 84 is biased into the energized state, the output of the detector 26 is shunted from the audio frequency amplifier 28 and the receiver is muted.

When the squelch circuit 40 is in the mute mode, a high voltage at the collector of the transistor 70 is applied to the base of the transistor 52 via the feedback resistor 74. The increased voltage at the base of transistor 52 means that the AGC voltage must be lower than necessary to operate the squelch circuit 40 in a mute state, and therefore the RF signal level must rise further. Therefore, this squelch circuit has a hysteresis characteristic, and the extent thereof is controlled by the resistance values of the resistors 74 and 46. The effect of hysteresis is the extent to which a received signal fades below the signal level required to transition to a non-mute state before the receiver is muted when the receiver is in a non-mute state. Thus, the device does not remain muted while the fading signal is incoming.

It should be noted that the threshold level required to convert the squelch circuit from the mute state to the non-mute state can be manually adjusted by setting the potentiometer 58. It is also important to note that temperature compensation is provided for ambient temperature at which the junction between the emitter and base of transistor 52 tracks the conduction voltage between emitter and base of transistor 52.

The squelch circuit 40 operates by the push-to-talk switch 36 to mute the receiver 10 for a defined period after converting the radio transceiver from a transmit mode to a receive mode. This works as follows: When the push-to-talk switch 36 is placed in the transmit mode, the B ⁺ potential of the receiver becomes zero and the delay capacitor 76 discharges.

When the push-to-torque switch 36 is switched to the reception mode, the B ⁺ potential of the receiver is high and the emitter potential of the transistor 70 is high. However, as the delay capacitor 76 keeps the base potential of the transistor 70 at a low potential for a while, and forward biases the transistor 70 to the saturation state, the buffer transistor 84 is energized so that the receiver ( Mute 10). The mute state during this delay is such that the transient value that occurs as the radio transceiver switches from the communication mode to the receiving mode disappears before the receiver 10 is unmuted, and the capacitance value of the capacitor 76 and By selecting the resistance value of the resistors (80) and (82) can be adjusted constantly. Thus, in the absence of such a device as described above, an unpleasant transient signal that may be reproduced in the speaker 30 is muted.

In summary, the squelch circuit according to the present invention can be suitably used particularly for a wireless transceiver. In the squelch circuit of the present invention, there is a hysteresis response that allows fading of the received signal without muting the receiver, and means for muting the receiver for a specified time after switching the radio transceiver from the transmit mode to the receive mode. It is provided.

Claims (1)

A squelch circuit adapted for use in a receiver section having AGC signal providing means of a radio transceiver having a switching means for selecting either a transmission mode or a reception mode, the receiver being not muted when the RF signal is increased, Transistors 52, 70 and a number of bias resistors 46, 54, 56, 60, 62 and 72 to mute the receiver as the RF signal decreases. Hysteresis squelch circuit composed of (74) and a potentiometer (58).

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