KR960000106Y1 - Polarizer - Google Patents

Abstract

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Description

Driving signal relay circuit of polarizer

1 is a circuit diagram of an embodiment according to the present invention

* Explanation of symbols for main parts of the drawings

10 pulse width-to-voltage conversion means 11 waveform transformation means

12: integration means 20: voltage-current conversion means

21 amplification means 22, 23 first and second voltage-current conversion circuit

24: output stabilization means A1 to A4: operational amplifier

D1: diodes ZD1, ZD2: first and second zener diodes

Q1, Q2: First and second transistors C1 to C3: capacitors

R1 to R14: Resistance VR: Variable resistor

The present invention relates to a polarizer in a microwave reception system, and more particularly to a circuit for driving a radio wave lens.

In general, microwave is a general term for frequencies ranging from 1 GHz to 10 GHz, and the wavelength is very short, about 3 to 30 cm.

In order to transmit information without error using the microwave, a fairly wide frequency band should be allocated to one information transmission channel. In order to solve this problem, microwaves are divided into frequency bands of vertical polarization components that proceed in the direction perpendicular to the earth and horizontal polarization components that progress in the direction horizontal to the earth. Allocates a band to one information transmission channel. The polarizer is a device for separating only one polarization of the vertical polarization and the horizontal polarization of the microwave received by the antenna, comprising: a waveguide connected between the antenna and the microwave processing circuit, a radio wave lens inserted between the waveguide, And a driving circuit for driving the radio wave lens. The driving circuit of the electronic lens has three methods, such as a mechanical system, a ferrite system, and a macon system, depending on the type of control signal.

First, a mechanical driving circuit inputs a pulse width modulation signal (PWM) as a control signal from a processor, and drives the motor according to the pulse width of the PWM. Adjust the rotation position of the radio wave lens by the rotation force of.

Secondly, the ferrite driving circuit generates an electromagnetic force of a different size according to the amount of current applied as a control signal from the control device to adjust the rotation position of the radio wave lens.

In addition, the Marconi-type driving circuit adjusts the rotation position of the radio wave lens according to the switching state of two kinds of operating voltages applied from the power supply device controlled by the control device. Among the three types of driving circuits, the mechanical method is mainly used since the development of the processor, and the position of the radio lens by the up-down key attached to the remote controller by the user. This is because it can be easily adjusted. Unlike the PWM, which is a control signal applied to the mechanical driving circuit, the ferrite driving circuit uses a current signal as a control signal, so that the ferrite driving circuit uses a current as a control signal unlike the PWM, which is a control signal applied to the mechanical driving circuit. Since a signal is used, it cannot be used by being connected to a processor instead of the mechanical driving circuit.

Therefore, an object of the present invention is to polarize the ferrite drive circuit to the drive signal of the ferrite drive circuit in order to make the ferrite drive circuit compatible with the mechanical drive circuit. It is to provide a signal relay circuit.

In order to achieve the above object, the present invention provides a polarizer including a ferrite lens driving circuit for driving a radio wave lens positioned in the middle of the waveguide,

Pulse width-voltage converting means for introducing a fill width modulation signal, which is a control signal for a mechanical lens driving circuit, through an input terminal and converting it into a voltage signal having a different size according to the pulse width of the pulse width modulation signal; And a voltage-current conversion means for converting the voltage signal output from the voltage conversion means into a current signal and supplying it to the ferrite lens driving circuit.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a circuit diagram of an embodiment according to the present invention, the configuration is as follows.

The pulse width-voltage converting means 10 may include a first operational amplifier A1, a capacitor C1, a variable resistor VR, and the like in order to modify a waveform of a pulse width modulated signal flowing through the input terminal IP into a triangular wave form. Waveform transforming means (11) consisting of three resistors (R1 to R3), and second operational amplifier (A2) and diode (D1) for integrating the output of the waveform modifying means (11) with reference to a second supply voltage. And a third grinding unit having a voltage follower function for buffering the output of the integrating means 12 and supplying it to the next stage as it is, by integrating means 12 including a resistor R4 and a capacitor C2. An amplifier A3.

The voltage-to-current conversion means 20 is an amplification means consisting of a fourth operational amplifier (A4) and three resistors (R5 to R7) in order to amplify the output voltage of the third operational amplifier (A3) at a constant 21 and a first zener diode ZD1 and a first transistor Q1 and two resistors R8 and R9 for converting a change in negative voltage during output of the amplifying means 21 into a positive current change. The first voltage-to-current conversion circuit 22 and the second zener diode ZD2 and the second transistor Q2 for converting the change of the positive voltage during the output of the amplifying means 21 into the negative current change. And a second voltage-current conversion circuit 23 composed of two resistors R10 and R11, and an output current amount of the first and second voltage-current conversion circuits 22 and 23 stably through the output terminal 0P. Output stabilization means 24 comprising a varistor VD, a capacitor C3, and three resistors R12 to R14 for transmission to a ferrite drive circuit. It is configured.

Next, the operation of FIG. 1 will be described in detail.

Waveform modifying means 21 is a waveform of the pulse width modulated signal to a triangular wave signal to be described in detail as follows. Variable resistor with one tap connected to the first supply voltage source Vcc through a resistor R1, the middle tap connected to the non-inverting terminal of the first operational amplifier A1, and the other tap connected to the ground voltage source GND. (VR) divides the first supply voltage to have a voltage level of a medium voltage among the voltage switching widths of the pulse width modulation signal, and divides the divided voltage into a non-inverting terminal of the first operational amplifier A1 as a reference voltage. do. The first operational amplifier A1 compares the voltage of the pulse width modulated signal flowing from the input terminal IP to the inverting terminal through the resistor R2 with the reference voltage supplied from the variable resistor VR. While the voltage of the signal is greater than the reference voltage, the capacitor C1 connected between the inverting terminal and the output terminal charges the difference voltage between the two voltages so that a negative voltage is induced at the output terminal. While the voltage is smaller than the reference voltage, the capacitor C1 is charged with the difference voltage between the two voltages so that the positive voltage is induced at the output terminal. At this time, the resistor R3 connected in parallel to the capacitor C1 provides a discharge passage of the capacitor C1 when the charging direction of the capacitor C1 is changed. As a result, a triangular wave having a negative voltage change is induced on the output terminal of the first operational amplifier A1 according to the charging direction and the charging voltage of the capacitor C1.

The integrating means 12 extracts and smoothes a voltage higher than or equal to the second supply voltage among the triangular wave-shaped voltages output from the waveform modifying means 11, and then supplies the same to the third operational amplifier A3. same. The second operational amplifier A2 flows into the non-inverting terminal from the output terminal of the first operational amplifier A1 and the voltage on its output terminal fed back to the inverting terminal through the anode and the cathode of the diode D1. When the voltage on the inverting terminal is greater than the voltage on the non-inverting terminal compared to the voltage of the triangular waveform, a logic signal having a negative logic state is supplied to the anode of the diode D1, and the voltage on the inverting terminal is on the non-inverting terminal When the voltage is smaller than the voltage, a logic signal having a positive logic state is supplied to the anode of the diode D1.

The diode D1 supplies only the logic signal of the positive logic state among the voltages on the output terminal of the second operational amplifier A2 to the inverting terminal of the third operational amplifier A3 and the second operational amplifier A2. At this time, the capacitor C2 connected between the cathode of the diode D1 and the second supply voltage source (-Vcc) performs charge / discharge operation according to the output voltage of the diode D1 using the second supply voltage as a base voltage. The resistor R4 connected in parallel with the capacitor C2 provides a discharge passage to the capacitor C2 during the discharge operation of the capacitor C2. The charge / discharge rate of the capacitor C2 is determined by the multiplication of the capacitance of the capacitor C2 and the resistance of the resistor R4.

The third operational amplifier A3, which operates as a voltage follower by connecting the inverting terminal to the output terminal, receives the integrated voltage on the cathode of the diode D1 flowing into the non-inverting terminal through the resistor R5. It is transmitted to the inverting terminal of (A4), and also performs a function of buffering so as not to affect the second operational amplifier (A2) side by the voltage variation of the fourth operational amplifier (A4) side.

Therefore, the pulse width-to-voltage converting means 10 composed of the waveform modifying means 11, the integrating means 12, and the third operational amplifier A3 serving as a buffer function element is produced according to the pulse width of the pulse width modulated signal. It converts into a voltage signal having a different voltage size.

The amplifying means 21 inverts and amplifies the output voltage of the third operational amplifier A3 at an amplification factor (-1). The resistor R5 connected between the output terminal of the third operational amplifier A3 and the fourth operational amplifier A4 has a current limiting function for limiting the output current of the third operational amplifier A3. Is connected to the inverting terminal of the fourth operational amplifier A4, and the other terminal is output from the fourth operational amplifier A4 through the emitter and base of the first transistor Q1, the first zener diode cathode, and the anode. The resistor R6 connected between the terminals functions to return the output voltage of the fourth operational amplifier A4 when the output voltage of the third operational amplifier A3 has a positive voltage. The fourth operational amplifier (A4) is connected to the inverting terminal and the other terminal of the fourth operational amplifier (A2) through the emitter and base of the second transistor (Q2) and the anode and cathode of the second zener diode (ZD2). The resistor R7 connected to the output terminal of A4) is the output voltage of the third operational amplifier A3. When the negative voltage has a negative voltage, the voltage on the output terminal of the fourth operational amplifier A4 is returned to the inverting terminal of the fourth operational amplifier A4. The fourth operational amplifier A4 inverts and outputs the output voltage of the third operational amplifier A3 to the anode of the first zener diode ZD1 and the cathode of the zener diode. In the case of the voltage of the output negative of A3), the output of the third operational amplifier A3 is inverted and amplified by the two resistors R5 and R7, and the output of the third operational amplifier A3 has a positive voltage. At this time, the output of the third operational amplifier A3 is inverted and amplified by the two resistors R5 and R6.

When the output voltage of the amplifying means 21 has a negative voltage, the first voltage current converting circuit 22 converts the signal into a positive current signal having a different magnitude depending on the magnitude of the negative voltage. The first zener diode ZD1 having the cathode connected to the first supply voltage source Vcc through the resistor R9 and the anode connected to the output terminal of the fourth operational amplifier A4 is connected to the fourth operational amplifier ( Only when the output voltage of A4) is lower than the voltage of the first supply voltage source Vcc by an amount greater than its own operating voltage, the resistor R9 and its cathode and anode are supplied from the first supply voltage source Vcc. A current path leading to the output terminal of the four operational amplifier A4 is formed, and the voltage of the first supply voltage source Vcc applied to the base of the first transistor Q1 is transferred to the output terminal of the fourth operational amplifier A4. Reduce by voltage magnitude. At this time, the voltage on the base of the first transistor Q1 is almost inversely linearly proportional to the voltage on the output terminal of the fourth operational amplifier A4 in the negative direction.

The first transistor Q1 is the first supply voltage source Vcc when the emitter and the differential voltage generated as the voltage on the base is reduced by the first zener diode ZD1 are equal to or greater than the operating voltage (0.4 or 0.7V). ) Forms a current path leading to the output terminal OP through the resistor R8 and its emitter and collector and the resistor R12, and the amount of current flowing through the current path is the emitter and base of the transistor Q1. As the voltage difference between them increases, they increase in a positive direction in proportion.

When the output voltage of the amplifying means 21 has a positive voltage, the second voltage current converting circuit 23 converts the negative current signal having a different magnitude according to the magnitude of the positive voltage. The second zener diode ZD2 having the anode connected to the second supply voltage source (-Vcc) through the resistor R9 and the cathode connected to the output terminal of the fourth operational amplifier A4 is connected to the fourth operational amplifier. Only when the output voltage of (A4) is greater than the voltage of the second supply voltage source (-Vcc) by an amount greater than its own operating voltage, from the fourth operational amplifier (A4) through its cathode and anode and the resistor (R11). A current path leading to the second supply voltage source (-vcc) is formed to increase the voltage applied to the base of the second transistor Q1 in proportion to the voltage level on the output terminal of the fourth operational amplifier A4. .

At this time, the voltage on the base of the second transistor Q2 is almost inversely linearly proportional to the voltage on the output terminal of the fourth operational amplifier A4 in the positive direction. The second transistor Q2 supplies a second supply when the voltage difference between the base and the emitter generated as the voltage on the base is increased by the second zener diode ZD1 becomes equal to or greater than the operating voltage (0.4 or 0.7V). A current path is formed from the voltage source (-Vcc) to the output terminal (0P) through the resistor (R10), its emitter and the collector, and the resistor (R12), and the amount of current flowing through the current path is transferred to the transistor (Q1). As the voltage difference between the base and emitter increases, it proportionally increases in the negative direction.

The output stabilization means 24 stably transmits the positive or negative current signal converted by the first and second voltage-current conversion circuits 22 and 23 to the ferrite driving circuit through the output terminal OP. It demonstrates in detail. A resistor R12 having one terminal connected in common to both collectors of the first and second transistors Q1 and Q2 and the other terminal connected to the output terminal 0P, and between the output terminal OP and the ground voltage source GND. The resistor R13 and the capacitor C3 connected in series with each other and the resistor R14 connected between the output terminal OP and the electromotive voltage source GND are connected to the output terminal when the first voltage-current conversion circuit 22 operates. The voltage on the OP and the voltage on the output terminal OP when the second voltage-current conversion circuit 23 operates are kept the same. In addition, the varistor VD connected between the output terminal OP and the ground voltage source GND prevents a surge phenomenon in which the voltage on the output terminal OP increases or decreases momentarily.

As a result, the voltage-to-current converting means 20 comprising the amplifying means 21, the first and second voltage-current converting circuits 22 and 23 and the output stabilizing means 24 is the pulse width-voltage modulating means 10 The output voltage is converted into a current signal and supplied to the ferrite driving circuit through the output terminal OP.

As described above, the present invention converts the pulse width modulation signal for driving the mechanical driving circuit into a current signal, which is a driving signal for the ferrite driving circuit, and supplies it to the ferrite driving circuit, thereby making the ferrite driving circuit compatible with the mechanical driving circuit. There is an advantage to this.

Claims (1)

In a polarizer including a ferrite lens driving circuit for driving a radio wave lens positioned in the middle of the waveguide, Pulse width-voltage conversion means for introducing a pulse width modulation signal, which is a control signal for a mechanical lens driving circuit, through a pressure stage and converting the pulse width modulation signal into a voltage signal having a different size according to the pulse width of the pulse width modulation signal; And a voltage-current conversion means for converting a voltage signal output from the pulse width-voltage conversion means into a current signal and supplying the ferrite-type lens driving circuit.