KR100434342B1 - Transmitter of base station for wireless communication network - Google Patents

Abstract

The present invention is to provide a base station transmitter of a wireless communication network capable of measuring the standing wave ratio of the transmission antenna of the base station and transmission power detection and automatic adjustment of the transmitter output by detecting the abnormality of the transmission path using a single transmitter circuit, The present invention includes a multi-contact switching means for receiving a signal coupled from the forward terminal and the reverse terminal of the directional coupler for outputting according to the control signal; Band filtering means for band-passing the output of said multi-contact switching means; Received signal strength index calculation means for calculating a signal strength index for the signal band-passed by the band filtering means; The directional coupler is sequentially controlled to connect the multi-contact switching means to the forward terminal of the directional coupler for the first time so that the signal of the corresponding forward path is input to the received signal strength index calculation means to detect the power thereof, and then the multi-contact point. The switching means is connected to the reverse terminal of the directional coupler so that the signal of the corresponding reverse path is inputted to the received signal strength index calculation means to sense the power, and measure the standing wave ratio of the transmitting antenna from the two power values. The signal strength index value reported by the signal strength index calculation means is compared with the set reference value to increase the attenuation value of the variable attenuator when the signal intensity index value is large, and to reduce the attenuation value of the variable attenuator when the signal strength index value is small. To control the transmission power automatically In addition, by using a single transmitter circuit, the transmission power and the standing wave ratio of the transmission antenna can be simultaneously measured, and the output of the transmitter can be automatically adjusted by detecting the final transmission power.

Description

Transmitter of base station for wireless communication network

The present invention relates to a base station transmitter of a wireless communication network, and more particularly, to a base station transmitter of a wireless communication network suitable for measuring the standing wave ratio of the transmission antenna of the base station and transmitting power detection and automatically adjusting the output of the transmitter using the same.

In general, a base station of a wireless communication network includes a transmitter circuit and a receiver circuit to exchange radio frequency signals for a subscriber station.

The prior art for a base station transmitter of such a wireless communication network includes three separate circuits: a circuit for measuring the transmission power, a circuit for measuring the standing wave ratio of the transmission antenna, and a circuit for automatically adjusting the output of the transmitter.

1 is a block diagram of a base station transmit power measurement circuit of a wireless communication network according to the prior art.

According to Figure 1, when measuring the transmission power of the transmitter circuit first receives the output signal of the directional coupler 10 is connected to the transmission antenna 80 to pass through the attenuator 20. The signal passed through the attenuator 20 is mixed with the signal generated by the local oscillator 70 and the frequency converter 30 is converted into a signal of a constant frequency.

The signal converted to a predetermined frequency passes through the band pass filter 40 and then amplified by the amplifier 50 and input to the signal detection unit of the RSSI 60. In general, RSSI (Received Signal Strength Indication) means a received signal strength index, and has a function of detecting the strength of the received signal. Accordingly, the RSSI 60 reports the signal to the upper control unit 90 after analog-to-digital conversion.

The transmission power is thus measured and reported to the upper controller 90.

2 is a block diagram of a standing wave ratio measuring circuit of a base station transmitting antenna of a wireless communication network according to the prior art.

According to FIG. 2, in the case of measuring the standing wave ratio of the transmitting antenna, the multi-point switch 11 and the single-contact switch 21 are first received by receiving the forward output of the directional coupler 10 connected to the transmitting antenna 80. Take it through. The signal passing through the single contact switch 21 is input to the band pass filter 31. The signal passing through the band pass filter 31 is input to the terminal 41, and the terminal 41 reports the strength of the input signal to the upper controller 51.

By applying the same method as the forward output, the reverse output of the directional coupler 10 reflected from the transmitting antenna 80 is input to the terminal 41, and the terminal 41 senses the strength of the input reverse signal and the upper control unit ( 51). The upper control unit 51 calculates the standing wave ratio using the strengths of the forward output and the reverse output of the directional coupler 10.

This makes it possible to measure the standing wave ratio of the transmitting antenna.

3 is a block diagram of a base station transmitter output control circuit of a wireless communication network according to the prior art.

According to FIG. 3, when automatically adjusting the output of the transmitter, the baseband signal is first input to the transmitter and mixed by the frequency converter 12 with the signal generated through the local oscillator 102. The mixed signal passes through the band pass filter 22 and the amplifier 32 in turn. The output of the amplifier 32 is attenuated through the variable attenuator 42 and then outputted to the outside of the transmitter via the amplifier 52 and the directional coupler 62.

The signal output through the directional coupler 62 in the transmitter passes through the external amplifier 72 and the band pass filter 82 and finally through the directional coupler 10. And the output signal is sent through the transmit antenna (80).

Here, the forward output of the directional coupler 62 located at the output in the transmitter for automatic adjustment of the transmitter output is input to the output sensing circuit 92, and the output sensing circuit 92 converts this output into a voltage. The voltage value is compared with the voltage value received from the controller 112, and the controller 112 adjusts the variable attenuator 42 on the transmitter path based on the result of the comparison of the voltage values so that a constant output is output from the transmitter output stage. To do that.

As described above, the above-described prior art configures transmission power measurement, transmission antenna standing wave ratio measurement, and transmission power automatic adjustment as separate circuits. Therefore, the prior art requires a separate circuit pack for measurement and adjustment in addition to the transmitter, which complicates the system configuration of the base station and increases the circuit pack configuration cost accordingly.

The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to measure the standing wave ratio and transmit power of the transmitting antenna of the base station by detecting the presence or absence of a transmission path using a single transmitter circuit. It is to provide a base station transmitter of a wireless communication network to automatically adjust the output of the transmitter.

In order to achieve the above object, a base station transmitter of a wireless communication network of the present invention includes: a multi-contact switching means for receiving a signal coupled from a forward terminal and a reverse terminal of a directional coupler and outputting the signal according to a control signal; Band filtering means for band-passing the output of said multi-contact switching means; Received signal strength index calculation means for calculating a signal strength index for the signal band-passed by the band filtering means; The directional coupler is sequentially controlled to connect the multi-contact switching means to the forward terminal of the directional coupler for the first time so that the signal of the corresponding forward path is input to the received signal strength index calculation means to detect the power thereof, and then the multi-contact point. The switching means is connected to the reverse terminal of the directional coupler so that the signal of the corresponding reverse path is inputted to the received signal strength index calculation means to sense the power, and measure the standing wave ratio of the transmitting antenna from the two power values. The signal strength index value reported by the signal strength index calculation means is compared with the set reference value to increase the attenuation value of the variable attenuator when the signal intensity index value is large, and to reduce the attenuation value of the variable attenuator when the signal strength index value is small. To control the transmission power automatically A base station transmitter of a wireless communication network, characterized in that it further comprises.

1 is a block diagram of a base station transmit power measurement circuit of a wireless communication network according to the prior art.

2 is a block diagram of a standing wave ratio measuring circuit of a base station transmitting antenna of a wireless communication network according to the prior art;

3 is a block diagram of a base station transmitter output control circuit of a wireless communication network according to the prior art;

4 is a block diagram of a base station transmitter of a wireless communication network according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10, 62: directional coupler 11, 122: multi-contact switch

12, 30: frequency converter 20: attenuator

21: Single contact switch 22, 31, 40, 82, 132: Band filter

31, 50, 52, 72: amplifier 41: terminal

42: variable attenuator 51, 90, 112: control unit

60, 142: RSSI 70, 102: local oscillator

92: output sensing circuit 80: transmitting antenna

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

4 is a block diagram of a base station transmitter of a wireless communication network according to an embodiment of the present invention.

In this embodiment, a single base station transmitter circuit performs a function of measuring a standing wave ratio of a transmitting antenna, transmitting power detection, and automatically adjusting a transmitter output. Therefore, it is not necessary to have multiple circuit packs for these measurements and adjustments.

According to Fig. 4, the transmitter circuit of this embodiment includes a frequency converter 12 for frequency conversion of an input baseband signal, a band filter 1 22 for filtering a transmission band of a signal, and an amplifier 1 32 for signal amplification. And an amplifier 2 (52), a variable attenuator (42) for variably attenuating signal strength, a local oscillator (102) for oscillating a constant frequency and applying it to the frequency converter (12), and outputting The control unit 112 includes a control unit 112, a multi-contact switch 122, a band filter 2 132, and an RSSI 142.

In addition, an amplifier 3 72, a band filter 3 82, a directional coupler 10, and the like are provided on a path connected to the transmission antenna 80 from the outside of the transmitter circuit.

According to this configuration, the base station final transmission signal is input to the directional coupler 10 which is connected to the transmission antenna 80. The signal input to the directional coupler 10 is partially coupled to the forward terminal and the reverse terminal, and the signal is input to the multi-contact switch 122. Reverse coupling and forward coupling of the multi-contact switch 122 is selectively controlled by the controller 112.

The signal input through the multi-contact switch 122 passes through the band pass filter 2 132 and is input to the RSSI 142. The signal input to the RSSI 142 is calculated by the signal strength index of the corresponding signal is converted into a digital signal by the analog / digital converter and then reported to the controller 112.

The controller 112 applies a reported signal strength index to an internal algorithm to determine attenuation by giving a control signal for controlling the variable attenuator 42.

That is, the control unit 112 compares the reported value with a reference value owned by the controller and, when the value is larger than the reference value, signals the variable attenuator 42 to increase the attenuation degree, and vice versa. To reduce the attenuation. This process makes the signal strength of the final output constant. The reference value owned by the controller 112 may be appropriately set based on the radio environment and circuit characteristics of the base station. For example, if the reference value is set to a signal strength index value suitable for maintaining an optimal transmission output, the variable attenuator 42 may be compared by comparing the magnitude with the signal strength index value calculated by the RSSI 142 during operation of the transmitter circuit. The attenuation degree of can be calculated.

In this way, the output of the transmitter can be automatically adjusted, and at the same time, the control unit 112 can measure the transmission power of the currently output signal.

In addition, the controller 112 determines whether to connect the multi-contact switch 122 to the forward terminal or the reverse terminal of the directional coupler 10.

By controlling the connection direction of the directional coupler 10 it is possible to measure the standing wave ratio of the transmitting antenna. First, a signal coupled to the forward terminal of the directional coupler 10 is detected through the multi-contact switch 122 to sense the output power in the RSSI 142. Then, the multi-contact switch 122 is controlled according to the detected output power to sense the signal output through the reverse terminal of the directional coupler 10 in the RSSI 142. The power values of the two signals detected as described above may be calculated by the controller 112 to finally measure the standing wave ratio.

In general, the standing wave ratio represents the magnitude of the standing wave occurring on the transmission line and is calculated as the ratio between the maximum and minimum values of the standing wave. The standing wave ratio is divided into a voltage standing wave ratio (VSWR) and a current standing wave ratio (CSWR).

The following equation 1 holds for the standing wave ratio.

S_v: Voltage standing wave ratio

S_c: Current standing wave ratio

rho: reflection coefficient

Where the standing wave ratio is When the value is 1, the line is in a matched state.

Therefore, the control unit 112 detects the signal power transmitted from the directional coupler 10 to the transmit antenna 80 through the forward terminal, and detects the signal power transmitted from the corresponding transmit antenna 80 to the directional coupler 10 in the reverse terminal. After detection through, the reflection coefficient and the standing wave ratio are calculated using the forward power and the reverse power.

The embodiments described above are within the scope of various changes, modifications, and equivalents of the present invention. Therefore, the present invention is not limited to the description of the examples.

According to the base station transmitter of the wireless communication network of the present invention, the transmission power and the standing wave ratio of the transmission antenna can be simultaneously measured using a single transmitter circuit.

In addition, by applying the present invention, it is possible to automatically adjust the output of the transmitter by detecting the final output while simultaneously measuring the transmission power and the standing wave ratio of the transmitting antenna.

Claims (4)

In the transmitter, Multi-contact switching means for receiving signals coupled at the forward and reverse terminals of the directional coupler and outputting the signals according to a control signal; Band filtering means for band-passing the output of said multi-contact switching means; Received signal strength index calculation means for calculating a signal strength index for the signal band-passed by the band filtering means; The directional coupler is sequentially controlled to connect the multi-contact switching means to the forward terminal of the directional coupler for the first time so that the signal of the corresponding forward path is input to the received signal strength index calculation means to detect the power thereof, and then the multi-contact point. The switching means is connected to the reverse terminal of the directional coupler so that the signal of the corresponding reverse path is inputted to the received signal strength index calculation means to sense the power, and measure the standing wave ratio of the transmitting antenna from the two power values. The signal strength index value reported by the signal strength index calculation means is compared with the set reference value to increase the attenuation value of the variable attenuator when the signal intensity index value is large, and to reduce the attenuation value of the variable attenuator when the signal strength index value is small. To control the transmission power automatically Base station transmitter of a wireless communication network comprising a. delete The method of claim 1, And controlling the attenuation value of the variable attenuator to automatically adjust the transmission output, wherein the control unit detects the transmission output automatically adjusted by the attenuation value control as the transmission power of the corresponding transmitter circuit. delete