KR100354548B1 - Input protector for power amplifier in base station of mobile communication system - Google Patents

Abstract

The present invention relates to a base station of a digital cellular mobile phone or a personal mobile communication system (PCS), which is caused when an excessive input signal is applied to the amplifier due to a sudden increase in users and carelessness during the installation of a power amplifier. The present invention relates to a protection circuit for preventing damage to a power amplifier. The present invention provides an input circuit of a power amplifier in a base station of a mobile communication, comprising: signal detecting means for detecting a part of an input signal when a level of a signal input to a power amplifier along a signal line exceeds a preset input level; Automatic gain control means for constantly adjusting the signal level input to the power amplifier to a predetermined input level by using the detected signal, and temperature compensation for measuring the temperature around the input stage of the power amplifier to prevent the change of the input level according to the temperature. It comprises a means.

Description

Input protector for power amplifier in base station of mobile communication system

FIELD OF THE INVENTION The present invention relates to base stations of digital cellular mobile phones or personal mobile communication systems (PCSs), which are caused when excessive input signals are applied to an amplifier due to inadvertent user growth and inadvertent installation of a power amplifier in a cell. The present invention relates to a protection circuit for preventing damage to a power amplifier.

The base station of the mobile telephone is configured as shown in FIG.

The controller (control frame) 1 has a built-in CPU and includes a radio frequency generator (RFG) for generating a basic signal frequency of the base station, and the data line is connected to an executive cellular processor (ECP) to receive instructions from the ECP. The terminal performs all the work and reports to the ECP. When the terminal is busy, it continuously measures the field strength and handsoff to the adjacent base station when the signal is weak. When the terminal is in the base station, the command to send the identification number of the single-stage device and sends the terminal's ID to the ECP and reports to manage the home location register (HLR) or the visitor location register (VLR) when visiting another area when the terminal is initially registered. Play a role.

Transceiver (2) combines the wired and wireless, generates a unique channel to carry the voice to send to the transmitting antenna (6), and also transmits the radio wave received from the terminal through the PSTN mobile phone Send it to the exchange.

The weak power of the inherent channels generated in the transceiver (2) is amplified by strong aerial power in a power amplifier (PA) 3 and then filtered in the CAB (4) to 16 in the combiner (5). After the channel is synthesized, it is delivered to the transmitting antenna 6 and radiated.

On the other hand, the reception radio waves are received through the reception antenna 7 and input to the transceiver 2 via the signal distributor 8.

In the base station of the mobile communication configured in this way, the power amplifier 3 is a very expensive equipment, and is an important part that determines the call quality and the output quality of the mobile communication system. However, when the user suddenly congested in the cell, an excessive input signal is applied to the power amplifier. In addition, due to inadvertent handling when installing a power amplifier, excessive signals above the rating may be applied to the input of the power amplifier. Thus, conventionally, there is a problem that the power amplifier is damaged by an excessive input signal exceeding the rating.

Accordingly, the inventors of the present invention have invented a circuit that protects the power amplifier by normally transmitting the signal to the power amplifier at the signal level and attenuating the signal to the normal level at the transient input level.

An object of the present invention is to detect the signal input to the power amplifier automatically adjusts the gain to a certain level, and to maintain a constant level of the input signal that changes according to the temperature change, for protecting the base station power amplifier of the mobile communication system It is to provide an input signal limiting circuit.

1 is a schematic diagram of a base station of a mobile communication system.

2 is a circuit diagram of the present invention.

3 is a PCB pattern of the signal detection unit.

4 is a functional diagram of a detector.

<Description of Major Symbols in Drawing>

A control frame 1, a transceiver 2, a power amplifier 3, a CAB 4, a combiner 5, a transmit antenna 6, a receive antenna 7, Signal divider 8, signal line 10, signal attenuator 12, 13, antenna pattern 11, 31, signal detector 30, automatic gain control unit 50, temperature compensator 70, amplifier (33), detector 51, amplifier 53, input level regulator 55, first DC loop 57, second DC loop 59, temperature sensor 71, comparator 73, third DC loop ( 75), Constant Voltage Circuit (90), Constant Voltage IC (91)

The present invention provides an input circuit of a power amplifier in a base station of a mobile communication, comprising: signal detecting means for detecting a part of an input signal when a level of a signal input to a power amplifier along a signal line exceeds a preset input level; Automatic gain control means for constantly adjusting the signal level input to the power amplifier to the preset input level by using the detected signal, and temperature compensation for measuring the temperature around the power amplifier input stage to prevent the change of the input level according to the temperature. It comprises a means.

The signal detecting means detects a signal when the input level of the power amplifier is -1 dBm to +4 dBm, characterized in that the PCB pattern for receiving a signal emitted from the PCB pattern passing the signal input to the power amplifier.

The automatic gain control means includes a first DC loop for applying a constant DC voltage to the signal line, detection means for detecting a signal output from the signal detection means and converting the signal into a DC signal, and applying a DC voltage converted by the detector to the signal line. It consists of a 2nd DC loop.

The temperature compensating means includes temperature sensing means for sensing the temperature around the power amplifier input stage, comparing means for comparing the output signal of the temperature sensing means with a preset reference voltage, and inputting the signal line of the power amplifier according to the output signal of the comparing means. It consists of a 3rd DC loop which applies a DC voltage.

Hereinafter, an embodiment of a mobile communication system power amplifier input signal limiting circuit (hereinafter referred to as "the present circuit") according to the present invention will be described in detail with reference to a circuit diagram. The present invention is a circuit added to a line through which an RF signal input to a power amplifier in a base station of a mobile communication system flows.

In the circuit shown in Fig. 2, the signal input from the transceiver to the input terminal IN of the circuit is added to the signal line 10 flowing through the output terminal OUT to the power amplifier,

When the signal level input to the power amplifier exceeds the preset input level, the signal detector 30 for detecting a part of the input signal and the signal level input to the power amplifier using the detected signal are constantly adjusted to the preset input level. The automatic gain control unit 50, and the temperature compensation unit 70 for measuring the temperature around the power amplifier input stage to prevent the change of the input level according to the temperature.

There may be various methods for detecting a signal, but in this embodiment, a PCB pattern is used. Referring to FIG. 3, since the input signal passing through the signal line 10 is a very high frequency, the PCB pattern 11 serves as a radiation antenna, and the signal detector 30 serves as a reception antenna to receive the signal. A method of forming and detecting a PCB pattern 31 was used. The reception antenna pattern 31 needs to be adjusted in length such that λ / 4 of the frequency passing through the line by the λ / 4 (λ = wavelength) dipole principle.

The level of the signal detected above is configured to detect no signal when the transient value of the signal input to the input terminal IN of the signal line 10 is -1 dBm or less, and detect the signal when the signal is -1 dBm to +4 dBm. . Therefore, the distance d between the radiation antenna pattern 11 and the reception antenna pattern 31 should be maintained accordingly. In the above case d is about 0.3-0.5 mm.

2, it can be seen that the signal detector 30 further includes an amplifier 33 for amplifying the detected signal. The amplifier 33 is an MMIC AMP whose model number is ERA-4SM, and is intended to amplify the detected signal because it is very weak.

In order to supply the bias voltage to this amplifier 33, +12 VDC is applied through the resistors R5, R6, R7, and R8. 4 resistors R5, R6, R7, and R8 are used in parallel because a large amount of current flows, so that one resistor does not meet the power specification. In this embodiment, all the resistors of the circuit are used in the same specification, so the power specifications are set using four resistors as above.

In FIG. 2, the automatic gain control unit 50 includes a detector 51 for detecting a signal output from the signal detector 30 and converting the signal into a DC signal, an amplifier 53 for amplifying the DC output of the detector 51; The input level controller 55 controls the input level of the power amplifier by forming a DC loop by overlapping the input signal path of the power amplifier using the converted DC value.

The detector 51 converts an input high frequency signal into a DC signal using a zener diode D4 and a capacitor C6. That is, as shown in (a) of FIG. 4, when the high frequency signal passes D4 only by the positive period due to the rectifying action of D4, as shown in (b), the waveform passing through D4 becomes DC due to the charge / discharge action of C6. Is converted into a signal. The DC level output from the detector 51 depends on the level of the high frequency signal input. That is, in proportion to the magnitude of the transient input detected by the signal detector 30, the magnitude of the DC level, which is the output of the detector 51, changes. The amplifier 53 is used to amplify the amplifier because the output level of the detector 51 is low, and a 2904 OP amplifier is used.

The DC voltage amplified by the amplifier 53 is applied to the input level controller 55 to automatically maintain a constant level of the signal flowing through the signal line 10 (automatic gain control). The input level regulator 55 consists of a first DC loop 57 consisting of two diodes D1, 2 and a resistor R23, and a second DC loop 59 consisting of D3 and R23. The first DC loop 57 ensures that + 12V is always applied to the point "14" of the signal line 10, and the second DC loop 59 has a DC voltage DC converted from the signal detected by the signal detection unit 30. To be applied to the point "15". Therefore, the high frequency signal flowing through the signal line 10 according to the DC voltage difference between the point "14" and the point "15" always maintains the level preset by the DC voltage applied to the point "14".

2, the temperature compensator 70 includes a temperature sensor 71 for sensing a temperature around the power amplifier input terminal, and a comparator 73 for comparing the output signal of the temperature sensor 71 with a preset reference voltage. And a third DC loop 75 for applying a DC voltage to the signal line 10 of the power amplifier according to the output signal of the comparator 73. Motorola's LM335 was used as the temperature sensor 71, and the comparator used a 2904 op amp.

The reference voltage of the comparator 73 is set to the variable resistance VR1. When the reference voltage is set at an appropriate temperature and the output of the temperature sensor 71 is connected to the input of the comparator 73, the temperature sensor 71 according to the ambient temperature. The output voltage will be different (in general, the higher the temperature, the lower the signal level flowing into the signal line 10). Accordingly, the comparator 73 outputs a different DC voltage, forms a DC loop through L6, D6, and R24, and applies a DC voltage to the point “16” of the third signal line 10.

Therefore, according to the difference between the first DC loop 57 and the third DC loop 75, the high frequency signal having a predetermined level flows in the signal line 10 by the voltage set in the first DC loop 57.

The main components not described in the circuit of Fig. 2 will be described. Circuits 12 formed by R2, R3, and R4 on the signal line 10 and circuits 13 formed by R26, R27, and R28 are respectively attenuators added to the line itself, and inserted into the line. The capacitors C1, C2, C9, C12, C13, C14, and C16 are used to allow high frequency signals to flow but not DC signals. For high frequency signals, the capacitance is very small, 100 pF.

L1 of the signal detection unit 30, L2, L3 and L4 of the automatic gain control unit 50, L6 of the temperature compensation unit 70, and L5 of the signal line 10 are choke coils to block high frequency signals. And only DC signal flows. It can be seen that the inductance is very small (220 nH) to cut off the high frequency. Circuit 90 at the bottom right of FIG. 2 shows 7812 91 which is a constant voltage IC. The constant voltage of + 12VDC is output from + 27VDC.

As described above, specific embodiments of the base station power amplifier input limiting circuit according to the present invention have been described. However, the technical idea of the present invention may not be limited to the above-described embodiments. Those skilled in the art will be able to make various modifications based on the technical idea of the present invention.

As described above, according to the present invention, even when an excessive input signal is applied to the power amplifier due to inadvertent handling when an excessive input signal is applied to the power amplifier or a power amplifier is installed in the cell, it is consistently fixed. This can solve the problem of breaking the power amplifier.

Claims (9)

As an input circuit of a power amplifier of a mobile communication base station, It is formed of a second PCB pattern for receiving a signal emitted from the PCB pattern passing the input signal input to the power amplifier, if the level of the signal received by the PCB pattern exceeds a preset input level of the input signal Signal detecting means for detecting a part, A first DC loop for applying a constant DC voltage to the signal line; Detection means for detecting a signal output from the signal detection means and converting the signal into a DC signal; And a second DC loop for applying the DC voltage converted by the detector to the signal line, wherein the signal level input to the power amplifier is constantly adjusted to a preset input level by using the signal detected by the signal detecting means. Automatic gain control means, Temperature sensing means for sensing a temperature around a power amplifier input stage; Comparison means for comparing the output signal of the temperature sensing means with a preset reference voltage; It is composed of a third DC loop for applying a DC voltage to the input signal line of the power amplifier according to the output signal of the comparison means, comprising a temperature compensation means for measuring the temperature around the power amplifier input stage to prevent the change of the input level according to temperature An input signal limiting circuit for protecting a base station power amplifier of a mobile communication system. The input signal limiting circuit for protecting a base station power amplifier of a mobile communication system according to claim 1, wherein the signal detecting means detects a signal when the input level of the power amplifier is -1 dBm to +4 dBm. delete The input signal limiting circuit for protecting a base station power amplifier of claim 1, wherein the signal detecting means further comprises amplifying means for amplifying the detected signal. delete In claim 1, The detection means is a detection circuit using zener diode D4, The first DC loop 57 has a diode D1 having an anode connected to the point 14 where a DC voltage is applied to the signal line, a resistor R22 connected to the cathode of D1, an anode connected to the opposite end of the R22, and the cathode is connected to the signal line. Consisting of a diode D2 connected and a resistor R23 connected to the cathode and common ground terminal of D2, The second DC loop 59 is inserted into the signal line so that the anode of the diode D3 is connected to the point 15 at which the DC voltage converted by the detector is applied to the signal line, and the resistor R23 is connected to the cathode of the D3 and the common ground terminal. Is connected, An input signal limiting circuit for protecting a base station power amplifier of a mobile communication system, characterized in that a DC blocking capacitor C9 is inserted into a signal line between the first DC loop and the second DC loop. 7. The input signal limiting circuit of claim 6, further comprising an amplifier for amplifying the DC output of the detection means. delete 3. The third DC loop 75 includes a D6 inserted in the signal line so that the anode of the diode D6 is connected to a point 16 at which the output DC voltage of the comparator 73 is applied to the signal line. Resistor R24 is connected to the ground terminal, An input signal limiting circuit for protecting a base station power amplifier of a mobile communication system, characterized in that a DC blocking capacitor C12 is inserted into a signal line between the second DC loop and the third DC loop.