JPH0683082B2 - Transmission amplifier having transmission power control function - Google Patents

Description

The present invention relates to a transmission amplification device having a transmission power control function.

[Outline of Invention]

The present invention relates to a transmission amplification device having a transmission power control function, and controls the power supply voltage of a power supply circuit that supplies a power supply voltage to the transmission amplifier so that the power of a transmission signal output from the transmission amplifier becomes constant. When the transmission signal is supplied to the transmission amplifier and the transmission amplifier is in the operating state, the power supply current supplied from the power supply circuit to the transmission amplifier is detected, and the switch means interposed between the power supply circuit and the control circuit is turned on. By controlling so as to be configured, useless power consumption in the control circuit when a transmission signal is not supplied to the transmission amplifier is eliminated without external control.

[Conventional technology]

A conventional transmission amplification device having a transmission power control function will be described below with reference to FIGS. 2 and 3. First, the transmission amplification device of FIG. 2 will be described. (4) shows a transmission amplifier as a whole, which is composed of a transmission amplifier (power amplifier) (2) and a control circuit (3) for controlling the transmission power thereof. AT is a transmission antenna and is connected to the antenna output terminal t of the transmission amplification device (4).

(1) is a main device, and a transmission amplifier (modulated signal) from a modulator provided in the main device is transmitted through a transmission line to a transmission amplifier (2)
I am trying to supply it to. Further, (5) is a power supply provided on the main device (1) side, and the power supply voltage from this is supplied to the transmission amplifier (2) and the control circuit (3) through the transmission line.

[Problems to be solved by the invention]

Such a conventional transmission amplification device (4) includes a transmission amplifier (2).
If is composed of a class C, class B or class AB amplifier, there will be no wasteful power consumption when a transmission signal is not supplied to this, so there is no problem, but the control circuit (3) uses the transmission amplifier (2). Since it operates even when the transmission signal is not supplied to, power consumption is wasted.

In order to solve this point, a switch (6) is provided between the power source (5) and the control circuit (3) as shown in FIG. 3, and this is supplied from the main unit (1) through the transmission line. The switch (6) may be turned off when the transmission signal is not supplied to the transmission amplifier (2) under the control of the control signal.

However, in this way, the transmission signal from the main device (1) side to the transmission amplification device (4) side is transmitted by three transmission lines,
Power supply voltage and control signals must be transmitted.

In view of such a point, the present invention proposes a transmission amplification device having a transmission power control function capable of eliminating unnecessary power consumption in a control circuit when a transmission signal is not supplied to a transmission amplifier without external control. Is what you are trying to do.

[Means for solving problems]

A transmission amplification device having a transmission power control function according to the present invention includes a transmission amplifier (10), a power supply circuit (17) for supplying a power supply voltage to the transmission amplifier (10), and a transmission output from the transmission amplifier (10). A control circuit (24) for controlling the power supply voltage of the power supply circuit (17) so that the signal power becomes constant, and a switch means (27) interposed between the power supply circuit (17) and the control circuit (24), A power supply current detecting means for detecting a power supply current flowing from the power supply circuit (17) to the transmission amplifier (10) when the transmission signal is supplied to the transmission amplifier (10) and the transmission amplifier (10) is in an operating state. 26), and when the transmission signal is supplied to the transmission amplifier (10) and the transmission amplifier (10) is in an operating state, the switch means (27) is activated by the detection output of the power supply current detection means (26). It is characterized in that it is controlled to be turned on. Than it is.

[Action]

According to the present invention, when the transmission signal is supplied to the transmission amplifier (10) and the transmission amplifier (10) is in the operating state, the switch means (27) is activated by the detection output of the power supply current detection means (26). Controlled to turn on.

〔Example〕

An embodiment of the present invention will be described in detail below with reference to FIG. Reference numeral (10) is a transmission amplifier, which is a class C grounded-base transistor amplifier in this case. (13) is an NPN transistor for the amplification. The emitter of the transistor (13) is connected to the input terminal (11) to which a transmission signal (for example, a signal in the vicinity of 1.6 GHz) is supplied, and is grounded in a direct current manner through the choke coil (14). The collector of the transistor (13) is the antenna input terminal (12).
And is connected to one end of the choke coil (15). AT is a transmitting antenna.

A regulator (voltage stabilizing circuit) (17) stabilizes the unstable DC voltage supplied to the input terminal (16) and supplies it to the transmission amplifier (10).

Reference numeral (18) is an NPN transistor for variable impedance, the collector of which is connected to the input terminal (16), and the emitter of which is the collector of the transistor (13) through the power supply current detection resistor (26) and the choke coil (15). Connected to. A resistor (19) is connected between the base and collector of the transistor (18). The base of the transistor (18) is grounded between the collector and emitter of the level comparison NPN transistor (20) and between the cathode and anode of the Zener diode (21). (22), (37)
Is a resistor for voltage division, one resistor (22) of which is connected between the emitter of the transistor (18) and the base of the transistor (20), and one end of the other resistor (37) is the transistor (20). Connected to the base of.

Reference numeral (28) is a directional coupler as a transmission power detecting means for detecting the transmission power of the transmission amplifier (10). The detection output of the directional coupler (28) is supplied to and detected by a detection circuit composed of a diode (29) and a capacitor (30), and the detection output is used as a transmission power detection output by the comparator of the control circuit (24). (Operational amplifier) (35).

Next, the control circuit (24) will be described. The emitter of the transistor (18) is connected to the collector of the NPN type transistor (31) through the emitter and collector of the PNP type transistor (27) serving as a switching means. The base of the transistor (27) is connected to the connection midpoint of the choke coil (15) and the resistor (26) through the resistor (25). The transistor (27) and the resistors (25), (26)
Constitutes a switch circuit (23). A resistor (32) is connected between the collector and base of the transistor (31). The base of the transistor (31) is grounded through the cathode and anode of the Zener diode (33). The emitter of the transistor (31) is a potentiometer (34)
Grounded through. The reference voltage from the movable contact of the potentiometer (34) is supplied to the comparator (35) and level-compared with the transmission power detection output from the above-mentioned detection circuit (29, 30).

The comparison output of the comparator (35) of the control circuit (24) is supplied to the other end of the resistor (37) through the low pass filter (39) including the resistor (36) and the capacitor (38).

A transmission signal (BPSK modulated signal) is supplied to the input terminal (11) from a main device (not shown) through a transmission line.
Further, the input terminal (16) is supplied with an unstable power source voltage (for example, +35 V) from the main device through the transmission line.

Next, the operation of this transmission amplification device will be explained. The transmission amplifier (10) enters an operating state (amplification state) when a transmission signal (its negative half cycle) is supplied to the input terminal (11). When the transmission signal is not supplied to the input terminal (11), the transistor (13) is off. Therefore, at this time, the power supply voltage obtained at the emitter of the transistor (18) of the regulator (17) is applied to the collector of the transistor (13) through the resistor (26) and the choke coil (15), but the resistor ( No power supply current flows to 26).
Therefore, there is no voltage drop across the resistor (26),
The transistor (27) is off. Therefore, since the control circuit (24) is not supplied with the operating voltage, it does not operate. In addition, the voltage of the emitter of the transistor (18) is connected to the bases of the transistor (20) by the resistors (22), (3
Since the voltage obtained by dividing by the resistors 7) and (36) and the resistor between the output side of the comparator (35) and the ground is supplied, the voltage of the emitter of the transistor (18) becomes indefinite.

When the transmission signal is input to the input terminal (11), the transistor (13) is turned on in the negative half cycle, and the transistor (13) performs an amplifying operation. When the transistor (13) is turned on, a power supply current flows through the resistor (26) and the choke coil (15), causing a voltage drop across the resistor (26). Therefore, the transistor (27) is turned on, the operating voltage is supplied from the regulator (17) to the control circuit (24), and the control circuit (24) is brought into an operating state. Then,
A reference voltage is obtained at the movable terminal of the potentiometer (34), this is compared with the transmission power detection output by the comparator (35), and the comparison voltage is output to the output side. And
The voltage difference between the emitter voltage of the transistor (18) and the comparison voltage of the comparator (35) is the resistors (22), (37) and (3).
The sum of the voltage divided by the resistor of 6) and the comparison voltage is given to the base of the transistor (20), and the output power supply voltage of the regulator (17) is determined by this.
In this case, if the transmission power of the transmission amplifier (10) becomes high,
The power supply voltage applied from the regulator (17) to the transmission amplifier (10) becomes low and the transmission power becomes low. When the transmission power becomes low, the power is supplied from the regulator (17) to the transmission amplifier (13). The power supply voltage becomes high, and the transmission power is controlled to be high, so that the transmission power is constant.

The transmission amplifier (10) is not limited to the class C amplifier, but may be a class B or class AB amplifier.

〔The invention's effect〕

According to the present invention described above, it is possible to obtain a transmission amplifying device capable of eliminating unnecessary power consumption in the control circuit when a transmission signal is not supplied to the transmission amplifier without external control.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing an embodiment of the present invention, and FIGS. 2 and 3 are block diagrams showing a conventional example. (10) is a transmission amplifier, (17) is a regulator (power supply circuit), (24) is a control circuit, (26) is a resistor (power supply current detection means), and (27) is a transistor (switch means).

Claims (1)

[Claims] 1. A transmission amplifier, a power supply circuit for supplying a power supply voltage to the transmission amplifier, and a control circuit for controlling the power supply voltage of the power supply circuit so that the power of a transmission signal output from the transmission amplifier becomes constant. A switch means interposed between the power supply circuit and the control circuit, and a transmission signal is supplied to the transmission amplifier, and when the transmission amplifier is in an operating state, the power supply circuit flows to the transmission amplifier. A power supply current detection means for detecting a power supply current, and when the transmission signal is supplied to the transmission amplifier and the transmission amplifier is in an operating state, the switch means is turned on by a detection output of the power supply current detection means. A transmission amplification device having a transmission power control function, characterized in that it is controlled so that