CS230929B1 - Connexion for deblocking of part of information from radiosignal - Google Patents

Abstract

The invention relates to a blocking connection part of the radio signal information it contains, in addition to Phoenician, another, eg non-phonic digital modulation traffic is intended and, on the contrary, it is distracting. The essence of the invention lies in the involvement of the loyal circuit with different charging and discharging time constant that the control handles a signal from the noise silencer circuit and the output logic signal controls leakage or blocking the original signal from the silencer circuit noise, which in the usual way controls circuits receivers, including optimized timers noise silencer constants. The invention can be used in the fields where it is uses radios for transmission other than Phonic Information.

Description

The invention relates to a circuitry for blocking a portion of information at the beginning of each radio reception mode maintaining optimized auto-silencer time constants and receiver parameters.

So far, the radio signal has been received either by receivers equipped or not equipped with silencer circuits. When received without a noise silencer, when the carrier wave is interrupted, the amplified noise is emitted by the acoustic transducer, which is very unpleasant. Therefore, radio receivers usually have noise suppressor circuits to block the low-frequency amplifier when the carrier wave is interrupted. The charging and shifting constants are optimized so that the subjective impression is best even when moving and under changing reception conditions.

This principle is commonly used and satisfactorily addresses the blocking of noise in the transmission of photo information. If, in addition to the phonic information, other, e.g. digital, information is transmitted, e.g. at the beginning of each transmitted session, the receiver's low-frequency circuits are unlocked during the transmission of this information.

Digital information is usually transmitted with maximum modulation depth and at the output of the receiver at a high volume, subjectively perceived as much louder than in phonic operation. The transmission of digital information is very distracting and is unnecessary for Phoenician traffic because its content is intended for other devices and is decoded and indicated by special circuits. For these reasons, it is desirable that in addition to noise, digital or other undesirable information be blocked in the low-frequency amplifier. Blocking such information so that it is not audible could be done, for example, by analyzing the nature of the modulation.

However, the perimeter solution would be very complex. The proposed circuitry for blocking unwanted information, which is located at the beginning of each transmitted session at a predetermined time interval, utilizes changes to the voltage silencer circuit voltage levels to block this information. The basic requirement is that the original characteristics of the noise suppressors are unaffected during the transmission of the phonic modulation and exhibit optimal parameters including the possibility of manual control. A solution to a similar problem is not yet known. The proposed circuit fully meets all these requirements.

The principle of blocking a portion of the information located within a specified period of time at the beginning of each block of information transmitted by the radio channel is that the control signal from the silencer is applied directly to the first input of the third product gate and simultaneously through the first connected diode and the first resistor. to a first input of the second product gate and further through a parallel connected second resistor and a second diode to both interconnected inputs of the first product gate and to one terminal of the first capacitor whose second terminal is grounded, the output of the first product gate is connected to the second input of the second product gate; the output of which is connected to the second input of the third product gate and its output is connected to the first input of the fourth product gate, while the second input of this gate is connected to a manual control signal and the output of the fourth product gate is connected e output wiring.

The advantage of the invention is its great subjective and objective effect with maximum simplicity. Another advantage is that it allows you to repeat consecutive sessions quickly. The minimum time lag is approximately three times the loss of the control signal that the circuit is capable of bridging.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is illustrated in more detail in the accompanying drawings, wherein FIG. 1 shows the basic circuit and FIG. 2 is a variant of the solution with a second capacitor connected.

Fig. 1 shows a basic circuitry capable of blocking a portion of any information of a specified length located at the beginning of each radio reception mode. The circuit consists of four two-input negative-gate product gates, two resistors, two diodes and one capacitor. The wiring input is the first input 31 of the third product gate 3, where the first resistor 6 and the anode of the first diode 2 are also connected at one end. The second end of the first resistor 6 and the cathode of the first diode 2 are connected to the input 21 of the second product gate 2. one end of the other resistor 2 and the cathode of the other diode 8.

The other end of the second resistor 2 β of the second diode 8 is connected to both the interconnected inputs 11 and 12 of the first product gate 1. The first capacitor 2, which is grounded at the other end, is connected to these interconnected inputs 48 and 12. The output 33 of the first product gate 1 is connected to the second input 22 of the product gate 3. The output 33 of this gate is connected to the second input 32 of the third product gate 3i whose output 33 is connected to the first input 41 of the fourth product gate A. A fourth control gate A is connected to a manual control signal, the output of this gate being an output-wiring.

The operation of the basic circuit according to FIG. 1 proceeds as follows: The control signal from the logic level H silencer 20 is directly applied to the first input 31 of the third product gate 3. This signal appears on the first input 21 of the second product gate 2 by bridging the first resistor 6 diode 2 at the same time, while at both interconnected inputs 11 and 12 of the first product gate i, with a delay given by the second resistor 2 and the first capacitor 2 ·

Thus, for the duration of this delay, the logic level L is present at both interconnected inputs 11 and 12 of the first product gate 1 and thus at the output 13 of the first product gate 1 is brought to the second input 22 of the second product gate 2 and 21 of the second aND gate 2 is H level, the output 23 of gate level L is connected to the second input 32 of the third aND gate 3 to block the passage of the signal from the squelch noise 20 at the first input 31 of the third aND gate 3 · ^{After a} delay the second resistor ^{2, and} the first the capacitor 2 ^s ® at both interconnected inputs 11 and 12 of the first product gate 1 reaches level H, at the output 13 of the first product gate 1 connected to the second input 22 of the second product gate 2 there will be level L causing the H level at output 23 of the second product gate 2 which, at the second inlet 32 of the third product gate 3, permits a passageway signal flow from the silencer 20 circuit through the third product shaft 3 ·

When changing the signal from level H to L on the silencer 20, the first capacitor 2 discharges through the first resistor 6; the second resistor 2 is bridged by the second diode 8 and therefore the voltage and the time constant given by the first resistor 6a of the first capacitor 2 decrease at both the first input 21 of the second gate 2 and the two connected inputs 11 and 12 of the first gate 6. the noise level 20 at the level H to L is shorter than at the first input 25 of the second product gate 2 and at the first capacitor 2 reaches the level L, the output 23 of the second product gate 2 remains at the level H and the wiring does not respond to this failure the H level signal is restored

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Only after a longer outage does the first capacitor 2 a discharge ^. When the level H signal at the output of the silencer 20 is restored, the reconnection of the L level at the second input 32 of the third product gate 3 blocks the signal from the silencer 20 .

FIG. 2 shows a variant of the circuitry different from that of FIG. This capacitor improves the wiring characteristics in the case of rapidly recurring signal failures at the output of the silencer 20 shorter than a predetermined value by recharging to full voltage each time the signal is restored via diode 2 and discharging from the full whenever the signal fails. Tension. Otherwise, the wiring works the same as the wiring shown in Figure 1.

AND.

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The object of the invention is to objectively block some of the information from the received radio signal, which is not intended for phonic operation and which is disturbing in this operation. Subjectively, this blocking results in the elimination of any adverse effects which, in the operation without connection according to the invention, involve the reception of a radio signal which, in addition to phonic, also contains other, for example, digital information. Ia is usually transmitted with the maximum modulation depth, which results in a high volume in the acoustic transducer, much higher than when receiving phonic information. These sections with a high volume are perceived as very unpleasant or painful. The circuitry according to the invention completely eliminates this unfavorable phenomenon. At the same time, the operation of the silencer and receiver parameters are fully maintained.

The wiring can be used to block any information that is located within a specified period of time at the beginning of each block of information transmitted by the radio channel.

Claims (4)

SUBJECT OF THE INVENTION A circuit for blocking a portion of information from a radio signal that is located within a specified period of time at the beginning of each block of information transmitted by a radio channel, characterized in that the control signal from the noise suppressor circuit (20) is applied directly to the first input (31) of the third and through the parallel connected first diode (5) and first resistor (6) to the first input (21) of the second product gate (2) and further through the parallel connected second resistor (7) and second diode (8) to both interconnected inputs (11) and (12) of the first product gate (1) and one outlet of the first capacitor (9), whose second outlet is grounded, the output (13) of the first product gate (1) being connected to the second input (22) ) of the second product gate (2), whose output (23) is connected to the second input (32) of the third product gate (3) and its output (33) is connected to the first input (41) of the fourth product gate (4) ), while a manual control signal is connected to the second input (42) of the fourth product gate (4) and the output (43) of the fourth product gate (4) is the wiring output. 2. The unlocking circuit according to claim 1, characterized in that it consists of an inverter. that the first product gate (1) 3. The blocking connection is the outlet (33) of the third according to item 1, indicated by the product gate (3). by outputting the wiring in inverse 4. The blocking connection according to claim 1, characterized in that from the first input (21) of the second product gate (2), where both resistors (6) and (7) and the cathodes of both diodes (5) and (1) are connected at one end. 8), a second capacitor (10) is connected to the ground. 1 drawing