JP3088483B2 - Transmission power control method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission power control system, and more particularly to a system for controlling transmission power in a digital radio apparatus to a certain range.

[0002]

2. Description of the Related Art In a digital microwave radio apparatus,
The back-off of the transmission power amplifier increases due to the multi-value, and it is necessary to increase the level of the saturation means. Therefore, there is a disadvantage that the power consumption of the transmission power amplifier increases. A route using the same frequency is radiating. If the transmission power is increased, a problem of interference occurs.

As one means for solving these problems, there is a method in which a signal for controlling transmission power is transmitted by inserting it into a main signal on a reverse line (from the receiving side to the transmitting side).

A conventional system will be described with reference to FIG. In FIG. 3, when a signal transmitted from the A station is received by the B station, the B station inserts data corresponding to the reception level into data transmitted from the B station to the A station, and inserts the data into the A station. And the station A detects data corresponding to the reception level.
It controls the transmission output from the station to the station B.

That is, at the station A, the transmission data for the station B is modulated by the modulator 50, and the frequency is up-converted by the mixer 52 of the transmitter 51 based on the oscillation signal from the local oscillator 53. The signal is amplified by the output amplifier 54 and transmitted as a microwave.

The station B receives the signal, amplifies it with an amplifier 61 of a receiver 60, down-converts the frequency with an oscillating signal from a local oscillator 63 by a mixer 62, and converts the frequency down with an automatic gain control amplifier 64. The signal is amplified and demodulated by the demodulator 65.

At this time, the reception level at the receiver 60 is detected by the reception input detection section 66, and the detected reception level information is sent to the control signal transfer section 67 to create control data corresponding to the reception level. This is encoded by a code processing unit 68, and the encoded control data is inserted into a reverse line, that is, a transmission line from station B to station A by an insertion unit 70 of a modulator 69.

The output of the modulator 69 of the station B is transmitted to a transmitter 71, and the frequency is up-converted by a mixer 72 based on an oscillation signal applied from a local oscillator 73.
The signal is amplified by the output amplifier 74 and transmitted to the station A as a microwave.

At the station A, this is received by the receiver 55, demodulated by the demodulator 56, and the separating section 57 separates and extracts control data corresponding to the reception level at the station B. The coded control data is processed by the code processing section 58 and output to the control circuit 59 as a control signal.

The control circuit 59 controls the output of the output amplifier 54 in accordance with the control signal. If the reception level at the B station is low, the output is increased, and if the reception level is high, the output is reduced. Control.

[0011]

Therefore, in order to realize the conventional system, a separation / insertion circuit of a control signal digitized in the main signal system is required. Further, the control signal is inserted into the main signal. Is required, and the circuit scale increases. In addition, the transmission amount of the original data is reduced by the amount of transmission of the digitized control signal. Further, since the digitized control signal is demodulated and extracted once, it cannot be applied to the IF relay system used for economical multiplex radio in the future. That is, in the IF relay system, the received signal is only dropped once to an intermediate frequency and amplified and output. Therefore, since there is no modulator / demodulator, the control signal cannot be digitally processed.

Accordingly, it is an object of the present invention to provide a transmission power control system which can be applied to an IF relay system and minimizes an increase in circuit scale.

[0013]

In order to achieve the above object, according to the present invention, control information for controlling a transmitter output by indicating a reception level and decoding the reception level is indicated by transmitting a pilot carrier.

The principle configuration of the present invention will be described with reference to FIG.
FIG. 1 shows an example in which the transmission power of station B is controlled based on a pilot carrier transmitted from station A.

At the station A, the input level of the receiver 1 is detected by a reception input level detector 2 and the value is transmitted to a pilot carrier transmission controller 3.

In the pilot carrier transmission control section 3, a high level H and a low level L are set in advance, and are compared with the detection values of the reception input level detection section 2,
The result is output as control signals a, b, and c.
That is, if the detected value is higher than the high level H, the pilot carrier transmission control unit 3 outputs a control signal a to the pilot carrier transmitting unit 4, and if the detected value is lower than the low level L, the control signal c is output. If the value is intermediate between the high level H and the low level L, the control signal b is output.

In pilot carrier transmitting section 4, the control signal transmitted from pilot carrier transmitting control section 3 is a
The pilot signal of frequency f ₁ is transmitted to the transmitter 5 sends a pilot signal of frequency f ₂ when c when.
When the control signal is b, the pilot carrier transmitting unit 4
Does not transmit a pilot signal.

When the pilot signal f ₁ or f ₂ is transmitted from the pilot carrier transmitting section 4, the transmitter 5 combines the pilot signal with the transmission signal. The pilot signal f ₁ or f ₂ is inserted at a level that does not affect the main signal, and is transmitted to the B station by the transmitter 5.

At the B station, the signal received by the receiver 10 is branched, one is sent to the demodulator, and the other is transmitted to the pilot carrier detector 11, where the pilot signal f _{1 is} transmitted. Or f ₂
Is detected.

When pilot signal f ₁ is detected by pilot carrier detector 11 and transmitted to transmitter output level controller 12, transmitter output level controller 12 reduces the output of transmitter 9. controlling a transmitter 13, the transmitter output level control section 12 and the pilot signal f ₂ is detected is controlled so that the output of the transmitter 9 is increased. When the pilot signals f ₁ and f ₂ are not detected, the output level control of the transmitter 13 is not performed, and the output of the transmitter 13 is held as it is.

[0021]

When the reception signal at the station A falls below the low level L due to the fusing of the transmission signal from the station B to the station A by this series of operations, the transmission output of the station B is transmitted as described above. Increase. After that, phasing disappeared,
When the reception input at the station A increases above the high level H, control is performed to lower the transmission output of the station B below the high level H and return to the standard level between the high level H and the low level L.

Although FIG. 1 shows only the configuration for controlling the transmission power of station B, the transmission power of station A can be provided by providing a similar configuration, and bidirectional transmission power can be controlled. .

[0023]

FIG. 2 shows an embodiment of the present invention. 2, the same symbols as those in FIG. 1 indicate the same parts. In the station A, the receiver 1 includes an amplifier 1-1, a mixer 1-2, a low
It includes a cull oscillator 1-3, an automatic gain control amplifier 1-4, a detector 1-5, and an amplifier 1-6. Received signal is amplifier 1
The frequency is down-converted by the local oscillator 1-3 in the mixer 1-2 and amplified by the automatic gain control amplifier 1-4.

The reception input level detector 2 includes a comparator 2-
1, a comparator 2-2 and an inverter 2-3 are provided.
The comparator 2-1 given set voltage V _H corresponding to the high level H as described in FIG 1, the comparator 2-2 B -
Selection voltage V _L corresponding to the level L is given. V
_H > _VL . The AGC voltage V from the receiver 1 is applied to the comparators 2-1 and 2-2. Therefore V
≧ V not _H if comparator 2-1 but also the comparator 2-2 outputs "1", but the output "1" of the comparator 2-2 is inverted - is inverted to "0" by the motor 2-3 You. And V ≦ V
_{If L,} not only the comparator 2-1 but also the comparator 2-2 outputs "0", but the output of the comparator 2-2 is inverted to "1" by the inverter 2-3. If _VH <V < _{VL, the} comparator 2-1 outputs "0" and the comparator 2-2 outputs "1", but the output of the comparator 2-2 is output from the inverter 2-3. The determination is "0".

The pilot carrier transmission control unit 3 includes switches 3-1 and 3-2.
The connected an oscillator OC1 for oscillating pilot signal f _1, the switch section 3-2 oscillator OC2 for oscillating the pilot signal f ₂ is connected. Switch section 3-1, 3
-2 is on / off controlled by control signals "1" and "0" from the reception input level detector 2, and turns on when it is "1", for example.

The pilot carrier transmitting section 4 includes, for example, a hybrid. The transmitter 5 includes a hybrid 5-1, a mixer 5-2, a local oscillator 5-3, and an output amplifier 5-4. Hybrid 5-1
Is intended to synthesize a pilot signal f ₁ or f ₂ to the main signal, the transmission signal in the mixer 5-2 b - up to the transmission frequency by local oscillator 5-3, converter - is collected by the output amplifier 5-4 Output.

In the station B, the receiver 10 includes the amplifier 1
0-1, a mixer 10-2, a local oscillator 10-3, an automatic gain control amplifier 10-4, and a hybrid 10-5.
3, the frequency of the received signal is down-converted,
The signal is amplified by the automatic gain control amplifier 10-4.

The pilot carrier detector 11, bandpass filter 11-1 of the frequency f _1, the band filters 11-2 of the frequency f _2, detectors 11-3 and 11-4 are provided.

The transmitter output level controller 12 has a comparator 1
2-1 and 12-2 are provided. Comparators 12-1 and 12
Reference voltage V ₀ is set to -2. This reference voltage V ₀
, The band pilot signal f ₁ from the filter 11-1, 11-2 respectively frequencies f _1, when the pilot signal f ₂ frequency f ₂ is outputted, the comparator 1 accordingly
2-1 and 12-2 are selected to output a high-level signal "1".

The transmitter 13 includes an output amplifier 13-1, a mixer 13-2, and a local oscillator 13-3.
The transmission signal is supplied to the local oscillator 1 in the mixer 13-2.
The signal is up-converted to the transmission frequency by 3-3 and output by the output amplifier 13-1. This output amplifier 1
3-1 is configured so that its output can be controlled to increase or decrease by the control circuit 15 as described later.

Reference numeral 14 denotes a hybrid, which converts a signal transmitted from the receiver 10 into bandpass filters 11-1 and 11-.
It branches to two.

The control circuit 15 controls the transmitter 13 based on the high-level signal "1" and the low-level signal "0" transmitted from the comparators 12-1 and 12-2 of the transmitter output level controller 12. The magnitude of the output of the output amplifier 13-1 is controlled. For example, when the comparator 12-1 is "1" and the comparator 12-2 is "0", the output of the output amplifier 13-1 of the transmitter 13 is controlled so as to decrease. When the comparator 12-2 is "1", the output of the output amplifier 13-1 is controlled to increase. When both of the comparators 12-1 and 12-2 are "0", the previous output state is changed. Control to keep.

Next, the operation of one embodiment of the present invention will be described with reference to FIG. The signal received by the receiver 1 of the station A is amplified by an amplifier 1-
1 is down-converted by the mixer 1-2 and amplified by the automatic gain control amplifier 1-4 so that the output becomes constant. At this time, the detector 1-5 and the amplifier 1
-6, the AGC voltage V is detected.
1, 2-2.

[0034] When the AGC voltage V to be inputted to the comparators 2-1 and 2-2 of the V ≧ V _H, comparator 2-1,2-
2 outputs "1", but the output "1" of the comparator 2-2 is inverted by the inverter 2-3 to become "0".
Eventually, “1” is applied to the switch unit 3-1 while “0” is applied to the switch unit 3-2.
The pilot signal f ₁ output from the transmitter ₁ is transmitted via the pilot carrier transmitter 4 to the hybrid 5-1 of the transmitter 5.
, Is combined with the main signal, and transmitted from the transmitter 5.

In the receiver 10 of the station B, the signal obtained by synthesizing the pilot signal f ₁ is branched by the hybrid 10-5 and transmitted to the hybrid 14, and the bandpass filters 11-1 and 11-of the pilot carrier detector 11 are provided. 2, respectively.

[0036] In this case the pilot signal f ₁ is output from the bandpass filter 11-1, the detection output of the pilot signal f ₁ is applied to the comparator 12-1 from the detector 11-3, a comparator 12 -1 is a high level signal "1"
, But the comparator 12-2 outputs “0”.

Since the outputs of the comparators 12-1 and 12-2 are input to the control circuit 15, the control circuit 15 controls the output amplifier 13-1 so that the output of the transmitter 13 decreases.

By the way, the signal received by the receiver of the station A becomes smaller due to faging or the like, and the AGC voltage V becomes V ≦ V.
When the voltage becomes _VL , both the comparators 2-1 and 2-2 output "0" and the inverter 2-3 outputs "1", so that the switch unit 3-2 is turned on. pilot signal f ₂ is inserted into the main signal.

As a result, in the B station, the bandpass filter 11-2
Since the pilot signal f ₂ is outputted from this time comparator 12-1 is "0", the comparator 12-2 outputs "1". Thereby, the control circuit 15 controls the output amplifier 13-1 so that the output of the transmitter 13 increases.

When the AGC voltage V in the receiver 1 of the station A is in a state of _VH <V < _VL , the switch unit 3-1,
Since both the 3-2 "0" is applied, the pilot signals f _1, f ₂ are both not inserted into the main signal.

Therefore, in the station B, the comparators 12-1 and 12-1
-2 is "0", so the control circuit 15
Means that the output of the transmitter 13 is kept as it is.

Although FIG. 2 shows only the configuration for controlling the transmission power of the station B, it is needless to say that the transmission power of the station A is controlled by a similar configuration.

[0043]

In the past, a modulator was required on the transmitting side to transmit a control signal, and a demodulator was required on the receiving side for decoding. However, the present invention provides these modulators, Since a demodulator is not required, the present invention can be applied to an IF relay system. In addition, the circuit scale can be made smaller than before, and the cost can be reduced.

[Brief description of the drawings]

FIG. 1 shows a principle configuration diagram of the present invention.

FIG. 2 shows a configuration diagram of an embodiment of the present invention.

FIG. 3 shows a conventional example.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 receiver 2 reception input level detection unit 3 pilot carrier transmission control unit 4 pilot carrier transmission unit 5 transmitter 10 receiver 11 pilot carrier detection unit 12 transmitter output level control unit 13 transmitter

Continuation of the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) H04B 1/02-1/04 H04B 1/38-1/58 H04B 7/24-7/26 H04Q 7/06-7 / 38

Claims (1)

(57) [Claims] In a transmission power control method for controlling a reception level within a predetermined range, a reception input level detection means (2) for detecting a reception input level is provided on a receiving side.
Pilot carrier transmission control means (3) for selectively transmitting the pilot carriers of the type; and transmission means (5) for inserting the pilot carriers into the main signal. Pilot carrier detection means for detecting the pilot carriers on the transmission side. (11) and a transmitter output level control means (12) for outputting a signal for controlling a transmission output, transmitting reception level information on the reception side based on the presence or absence of the at least two types of pilot carriers. A transmission power control method characterized in that the presence or absence of these pilot carriers is detected by a pilot carrier detection means (11) and the transmitter output level control means (12) is controlled based on the detection.