DE2426649A1 - Battery operated radio receiver - has transistor switch controlled by pulses from astable multivibrator - Google Patents

Abstract

The multivibrator is permanently connected to the battery, and the keying ratio of its pulses is such that periods when the receiver is on are much shorter than periods when it is off. A holding circuit with an SC component responds to the reception of an h.f. carrier and holds the multivibrator in a state in which the receiver is on. It releases the multivibrator when the carrier disappears. Multivibrator and holding circuit consists of NAND circuits based on active components, combined into a monolithic integrated unit. Space requirements and power consumption are reduced by this simplified arrangement.

Description

Battery Operated Radio Receiving Apparatus The invention relates to to a battery-operated radio receiver with one in the battery circuit lying and the receiving device on and off transistor switch, with an astable multivibrator continuously fed from the battery, the one for alternating opening and closing of the switch serving pulse train of such duty cycle indicates that the switch-on times of the receiving device are considerably lower a-l-s - d-i-e - kusscha-ltzeiten are, and with a holding circuit having semiconductor components, which starts from the beginning of receiving a high frequency carrier to the astable multivibrator in a state holds, in which the transistor switch is closed, and the one at the end of the reception a high-frequency carrier releases the astable multivibrator again.

If radio receivers are powered by batteries, the required one depends Capacity of the batteries depending on the desired output power and the duty cycle of the devices. There are radio receivers, for example the receiving part of radiotelephony transmitters and receivers that must be ready to receive at all times. This inevitably leads to a relatively high power consumption at a large Battery weight and relatively large space requirements for these batteries. For portable Bare radios that are as light as possible should have, it is therefore worthwhile to find solutions that meet the demand for electricity can be reduced noticeably.

There is a known measure to save electricity for radio receivers therein, the power source at relatively short time intervals by means of a relay periodically on and off (DT-AS 1 135 969).

According to another known measure, an economy circuit is used, the battery power for a radio receiver in the absence of the reception signal automatically reduces by a switch with a below the hearing threshold Frequency switches the battery power on and off in such a way that the current flow time is considerable less than the blocking time, and by having a hold circuit keep the switch in the closed The state lasts as long as a received signal occurs at the receiver and after it has stopped it switches off with a delay (DT-AS 1 276 760>.

The last-mentioned economy circuit results in some expenditure on active and passive electrical components give satisfactory results.

The invention is based on the object of the known economy circuit to improve in such a way that their production is simplified, the space requirement is reduced and can reduce the power consumption for the radio even further.

According to the invention This object is achieved according to the invention in the case of a battery-operated radio receiver of the type mentioned at the outset solved that the astable multivibrator and the hold circuit based on NAND circuits containing active components are constructed to form a monolithic integrated module are summarized.

In the case of a radio device with the aforementioned features, this is simplified the production insofar as in particular by using monolithic integration only a few components that require little space for the NAND circuits are needed.

In an embodiment of the invention, a battery-operated radio device is used constructed in such a way that the astable multivibrator from a first and a second NAND circuit with two inputs and one output each is formed that the Output of each NAND circuit via a capacitor with one input each the other NAND circuit is connected that said inputs each via one Resistance are connected to one and the same pole of the operating voltage source and that the other inputs of the two NAND circuits are connected to the hold circuit are.

According to a further, particularly advantageous embodiment of the invention is a battery-operated radio receiver designed such that the hold circuit a third and a fourth NAND circuit and that the third NAND circuit in connection with one of the NAND circuits of the astable multivibrator a first first Flip-flop circuit and the fourth NAND circuit in conjunction with the other NAND circuit of the astable multivibrator form a second flip-flop circuit. One out of two Flip-flop circuits composite hold circuit for stopping or releasing the astable multivibrator has the advantage that the economy circuit works particularly precisely.

If, according to a further embodiment of the invention, the NAND circuits from astable multivibrator and holding circuit to a monolithically integrated component are combined in CMOS technology, then there is a compared to a Constructed from discrete components, low power consumption, which also increases the overall power consumption reduced.

Further details and expedient embodiments of the invention arise from the subclaims and are shown on the basis of one in the drawing Embodiment explained in more detail. In the drawing: FIG. 1 shows a block diagram of the battery-operated radio receiver according to the invention, FIG. 2 shows the temporal Behavior of a signal voltage at the output of the astable multivibrator, Fig. 3 that temporal behavior of the supply voltage for the radio receiver and Fig. 4 das Temporal behavior of the output voltage of a belonging to the radio receiving device Squelch.

In In Fig. 1 denotes the dash-dotted line Circuit part framed by lines is an astable multivibrator 1 and the one by dashed lines it lines framed circuit part a holding circuit 2 for the astable multivibrator. 3 with a radio receiving device is referred to, for example, the receiving part of a VHF two-way radio. Ds radio receiving device 3 has a connection 4 for Supply of a supply voltage us for the device and an output 5 to deliver a signal voltage supplied by a squelch of the device. Between the output 5 of the radio receiver 3 and an input 6 of the holding circuit 2 is located a diode 7. An output 8 of the astable multivibrator 1 is available via a Decoupling resistor 9 with the base of a transistor 10 in connection, the Emitter-colletor path in the supply line to connection 4 of the radio receiver 3 lies. While the emitter of the transistor 10 with the positive pole, for example a direct current source, for example a battery with the voltage UB is, the collector of this transistor is connected to terminal 4 of the radio receiver in connection.

The astable multivibrator 1 contains as essential components a first and a second NAND circuit 11, 12, each having a first input 13, 142 each have a second input 15, 16 and an output 17, 18 each. The exit 17 of the first NAND circuit 11 is firstly connected to the second via a capacitor 19 Input IS of the second NAND circuit 12 and secondly via a resistor 20 with the positive pole of the operating power source source connected. Of the Firstly, output 18 of the second NAND circuit 12 is available via a capacitor 2i to the second input 15 of the first NAND circuit 11 and secondly via a Resistor 22 also with the positive pole of the operating power source, that is a battery with the voltage UB in connection.

The output 18 of the second NAND circuit 12 also forms the Output 8 of the astable multivibrator 1.

The hold circuit 2 has a third and a fourth NAND circuit 23, 24, which also each have a first input 25, 26 and a second input 27, 28 and each have an output 29, 30. An RC circuit also belongs to the hold circuit from a parallel connection of a resistor 31 and a capacitor 32, the between the input 6 of the holding circuit 2 and ground. The input 6 of the hold circuit 2 is also connected to the first inputs 25, 26 of the third and fourth NAND circuits 23, 24 connected. The second input 27 of the third NAND circuit 23 is direct to the output 17 of the first NAND circuit 11 and the second input 28 of the fourth NAND circuit 24 is connected to the output 18 of the second NAND circuit 12. from the output 29 of the third NAND circuit 23 leads to a connection to the first Input 13 of the first NAND circuit 11 and from the output 30 of the fourth NAND circuit 24 a further connection to the first input 14 of the second NAND circuit 12.

the . The circuit described above has in the following mode of action: 1. Radio receiver does not receive any high-frequency carrier The radio receiving device 3 is ready to receive and is not a high-frequency carrier received, the squelch belonging to the radio receiving device gives no signal voltage ue ab; see also the voltage curve in FIG. 4. This means that it is at the first inputs 25 and 26 of the third and fourth NAND circuits 23, 24 have an L (low) signal of the resistor 31. Regardless of the signal at the second inputs 27 and 28 of the two NAND circuits 23 and 24, have the outputs of the latter NAND circuits have an H (high) signal.

As mentioned earlier, the first and second form NAND circuit 11, 12 in connection with the resistors 20, 22 and the capacitors 19, 21 an astable multivibrator that initially oscillates freely and a pulse train or a square-wave signal voltage, inter alia, corresponding to the voltage curve in Fig. 2 outputs at its output 8. The signal voltage ua has a pulse pause T1 of, for example, 10 ms and a pulse duration T2 of, for example, 100 ms. While which receives a pulse pause lasting from a point in time t1 to a point in time t2 thus the radio receiving device 3 a supply voltage us.-Will in the time between tl and t2 do not receive a high-frequency carrier, the squelch gives the radio reception device receiving device still no signal voltage ue. Of the The astable multivibrator 1 therefore continues to oscillate. Then begins at time t2 the pulse of the signal voltage, etc., the transistor 10 goes into the blocking state, and the radio receiving device 3 no longer receives a supply voltage u5; see.

Voltage curve in Fig. 3.

The radio receiver 3 is thus only in each case in the pulse pauses the signal voltage Ua is switched on for a period of about 10 ms, while it is switched on for the duration of 100 ms remains switched off. This will save electricity reached by about a tenth.

2. FunkemSfangsgerät receives a high frequency carrier Stands for example If a high-frequency carrier arrives at a point in time t3, the radio receiving device 3 Do not evaluate this carrier at first because it does not receive a supply voltage u5. Only at a point in time t4 (FIG. 2) when the signal voltage inter alia again has a pulse pause has, the radio receiver 3 is switched on, and its squelch is as a result of the received high-frequency carrier, a voltage ue that corresponds to an H signal is equivalent to. The H signal charges the capacitor 32 relatively via the diode 7 a short time. This gives the first inputs 25, 26 of the third and fourth NAND circuit 23, 24 an 'H signal.

In the following now form the NAND circuits 11, 23 and 12, 24 each a flip-flop circuit. Since at the first input 26 of the the fourth NAND circuit 24 now has an H signal and an L signal at the second input 28 (Pulse pause between times t4 and tE, Fig. 2), the output 30 emits an H signal. Furthermore, since the first input 14 of the second NAND- * circuit 12 has the H signal and the second input 16 also has an H signal the output 18 of the second NAND circuit 12 from a L signal.

So as long as the Funkemfpangsgerät 3 is on the supply voltage us and a high frequency carrier is received, becomes the astable multivibrator 1 is held in a state in which it outputs an L signal. As a result of the L signal at the output 18 of the second NAND circuit 12 or at the output 8 of the astable Multivibrator 1, the transistor 10 remains in the conductive state and the radio receiving device 3 switched on.

Just for the sake of completeness it should be mentioned that to the same Time the output 17 of the first NAND circuit 11 has an H signal.

If no more high-frequency carriers are sent from a point in time t6, so the squelch of the radio receiving device 3 no longer gives any signal voltage away. At this time, the RC circuit comes out of the resistor 31 and the capacitor 32 as well as the diode 7 to the effect. The voltage on capacitor 32 delivers the first inputs 25 and 26 of the NAND circuits 23 and 24 for a certain delay time tv an H signal.

The radio receiving device 3 thus remains until a point in time t7 switched on first The first inputs 25, 26 of the two NAND circuits 23 and 24 again an L signal so that the astable multivibrator 1 begins to oscillate again and the supply voltage u5 for the radio receiving device 3 is switched on and off periodically.

In addition, the delay time tv (Fig. 3) is therefore present, so that the radio receiver 3 is not switched off immediately when the high-frequency carrier, for example, as a result of a fault, only fails for a short time.

The NAND circuits 11, 12, 23 and 24 are expediently closed a monolithically integrated component, preferably in CMOS technology. This combination simplifies the structure and manufacture of the Circuit, and there is also a further power saving, because then the power consumption for the astable multivibrator 1 and the holding circuit 2 is only approx. 50 pA.

In the present example it was always assumed that in the entire receiving device is switched off during the switch-off times T2. In practice on the other hand, one often leaves the receiving device from the high-frequency input up to and including to work the squelch in continuous operation because the squelch is a non-negligible Response time. As a result, the switch-on time T1 can then be particularly short keep.

Claims (8)

Claims 1. Battery operated radio receiver with one in the battery circuit lying and the receiving device on and off transistor switch, with a Astable multivibrator continuously fed from the battery, one for alternating Opening and closing the switch serving pulse train such duty cycle indicates that the switch-on times of the receiving device are considerably shorter than the switch-off times are, and with a holding circuit having semiconductor components, which starts from the beginning of receiving a high frequency carrier to the astable multivibrator in a state holds, in which the transistor switch is closed, and the one at the end of the reception a high-frequency carrier releases the astable multivibrator again, characterized in that that the astable multivibrator (1) and the hold circuit (2) on the basis of NAND circuits (11, 12, 23, 24) containing active components are constructed, which are combined to form a monolithically integrated module. 2. Battery-operated radio receiver according to claim 1, characterized characterized in that the astable multivibrator (1) consists of a first and a second NAND circuit (11, 12) each with two inputs (13, 15; 14, 16) and one output each. gang (17, 18) is formed that the output of each NAND circuit via a capacitor (19, 21) each with one entrance of the other NAND circuit (11, 12) is connected that said inputs each via one Resistor (20, 22) connected to one and the same pole of the operating voltage source are and that the other inputs (13, 14) of the two NAND circuits with the hold circuit (2) are connected. 3. Battery-operated radio receiver according to claim 1, characterized characterized in that the hold circuit (2) has a third and a fourth NAND circuit (23, 24) and that the third NAND circuit (23) in connection with a the NAND circuits (z. B. 11) of the astable multivibrator (1) a first flip-flop circuit and the fourth NAND circuit (24) in communication with the other NAND circuit (e.g. 12) of the astable multivibrator form a second flip-flop circuit. 4. Battery-operated radio receiver according to claim 3, characterized characterized in that the first inputs (25, 26) of the third and fourth NAND circuits (23, 24) are connected to an input (6) of the holding circuit (2) at which only when Receiving a high frequency carrier a signal voltage (ue) with a certain Voltage value is that the input (6) of the holding circuit (2) via an RC circuit (31, 32) is connected to ground that the second inputs (27, 28) of the third and fourth NAND circuit (23, 24) each having an output (17, 18) of the first and second NAND circuit (11, 12) and the outputs (29, 30) of the third and fourth NAND circuit, each with a second input (13, 14) of the first and second NAND circuit are connected. 5. Battery-operated radio receiver according to claim 1 or one of the following claims, characterized in that the NAND circuits (11, 12, 23, 24) from astabilem.Multivibrator (1) and holding circuit (2) to a monolithic integrated module are summarized in CMOS technology. 6. Battery-operated radio receiver according to claim 1, characterized characterized in that the transistor switch has a transistor (10) whose emitter-collector path is in series with the battery circuit and its base via a decoupling resistor (9) is connected to the output (8) of the astable multivibrator (1). 7. Battery-operated radio receiver according to claim 4, characterized characterized in that the input (6) of the hold circuit (2) with the output of a squelch of the radio receiver (3) is connected, only for the duration of the reception of a High-frequency carrier emits a certain signal voltage. 8. Battery-operated radio receiver according to claim 1, characterized characterized in that the radio receiving device (3) is part of a VHF voice radio transmission and receiving device.