KR200156613Y1 - Transistor amplifying circuit - Google Patents

Abstract

The present invention relates to an intermediate frequency amplifier usable for a Korean fuse and a detector circuit thereof, and more particularly, to an intermediate frequency amplification transistor amplification circuit of a fuse receiver which can be manufactured in a small size with a wide frequency band of the amplifier, and an integrated circuit with the amplification circuit. It relates to a combined detector circuit.

The present invention is an intermediate frequency amplifier for amplifying an intermediate frequency signal, which is used in a shell fuse receiver, comprising: a capacitor for bypassing an input intermediate frequency signal and applying it to a transistor amplifier; A transistor to which an input signal through the capacitor is applied to the base and a power supply voltage is applied to the selector via a resistor; Two resistors for dividing the power supply voltage to bias the base of the transistor; A resistor connected between the emitter and the ground of the transistor to stabilize its bias; A capacitor connected in parallel with the resistor to bypass the high frequency signal; And, to output the intermediate frequency signal amplified by the transistor provides a transistor amplification circuit for the intermediate frequency amplification of the fuse receiver, characterized in that it comprises a capacitor connected to the collector for outputting only a high frequency signal. .

Description

Transistor amplification circuit for intermediate frequency amplification of fuse receiver

The present invention relates to an intermediate frequency amplifier usable for a Korean fuse and a detector circuit thereof, and more particularly, to an intermediate frequency amplification transistor amplification circuit of a fuse receiver which can be manufactured in a small size with a wide frequency band of the amplifier, and an integrated circuit with the amplification circuit. It relates to a combined detector circuit.

The fuse has the function of causing the initial process of the explosive chain to ignite and explode the peony of the explosive device.

All fuses shall have four functions: safety, loading, sensitivity and explosion. In the view of safety, the fuse shall be designed so that it does not work before the required time. It must also be safe during storage, loading, shipping, handling and launching.

The fuse is the second function and must be loaded at the appropriate time after firing. This may be achieved by properly utilizing natural phenomena that occur during the launching of the ammunition shell.

The fuse should also have the ability to detect the location of the target. In order to achieve this final purpose, it is possible to make contact with the target, to approach the target, to measure a scheduled jump time from launch or to measure the characteristics of the trajectory indicating the presence of the target.

As the last function of the fuse, the fuse should explode at a given time for optimum effect.

On the other hand, if the fuse of the shell is classified according to its function or function, it can be classified into an impact fuse, time fuse, peripheral fuse, proximity fuse, and command fuse.

Proximity fuses are equipped with electronic devices having the functions of transmitting and receiving in their fuses, and receiving signals reflected from the target by radio waves transmitted from the targets through the receiving device of the fuse, and detonating them at the optimum approach distance. Has the function to operate.

1 is a circuit diagram of an intermediate frequency amplifier formed in the prior art and a detector circuit in a receiver used in a receiving device of a fuse, and shows an example configured using an operational amplifier.

In the receiving device of a fuse, in order to make the weak signal received into a practical large signal, the received signal must be sufficiently heavy. For this purpose, two or more high frequency amplification circuits having a large amplification degree should be used, but in this case, the overall amplification of the entire high frequency amplification circuit is greatly increased, and a positive feedback occurs in this circuit, causing oscillation phenomenon.

Therefore, the input frequency is lowered to a separate low frequency and amplified again. To this end, a local oscillation circuit is installed, and the frequency oscillated in the oscillation circuit is mixed with the original frequency, and the output signal of the intermediate frequency corresponding to the difference between two frequencies is output.

The circuit shown in FIG. 1 is a circuit for amplifying the above-described intermediate frequency input using an operational amplifier, and detecting and demodulating the necessary signal.

In this circuit, the usable frequency is determined by the frequency band characteristics of the operational amplifier. Such operational amplifiers are significantly degraded at high frequencies due to the characteristics of their integrated circuits. Therefore, the amplifier cannot function at frequencies outside the bandwidth of the operational amplifier.

Since the band of the intermediate frequency used for the Korean fuse is about 2 MHz, it is higher than the appropriate bandwidth of the conventional operational amplifier.

At this time, an operational amplifier with a higher frequency band also requires a higher cost, and thus a cost problem arises.

On the other hand, in order to use the apparatus for fuses, the size of the operational amplifier and its associated circuit elements is required to be small.

The present invention has been made to solve the above problems, and has as its object to provide an intermediate frequency amplifier having excellent amplification degree in the frequency band applicable to the Korean fuse and can be made compact.

1 is an amplification circuit diagram of an intermediate frequency amplifier using a conventional operational amplifier,

2 is a circuit diagram of a transistor amplifier circuit for intermediate frequency amplification according to the present invention.

* Explanation of symbols for main parts of the drawings

200: intermediate frequency amplifier 300: envelope detection unit

Q 1: Amplifying Transistor D 1: Detection Diode

C 1, C 2, C 3, C 4: capacitors R 1, R 2, R 3, R 4, R 5, R 6: resistors

Vcc: Power Supply Voltage

In order to achieve the above object, the present invention is used in the receiver of the shell fuse, in the intermediate frequency amplifier for amplifying the signal of the intermediate frequency generated through the frequency conversion circuit, the intermediate frequency signal to bypass the transistor A capacitor for applying to the amplifier, an input signal through the capacitor is applied to the base, and a power supply voltage is divided into two to divide the voltage to bias the transistor power supply voltage applied to the selector through the resistor to the base of the transistor A resistor connected between the emitter and the ground of the transistor to stabilize the bias, a capacitor connected in parallel with the resistor to bypass the high frequency signal, and outputting an intermediate frequency signal amplified by the transistor. Connected to that collector Provides an intermediate frequency amplifier transistor amplifier circuit of the fuze, it characterized in that the receiver is formed by a capacitor for outputting only the high-frequency signal.

Example

Referring to the accompanying drawings, a preferred embodiment of the present invention will be described.

2 is a circuit diagram of an intermediate frequency amplifier and an envelope detector constructed in accordance with the present invention.

Since the intermediate frequency needs to be about 2 MHz in order to apply to the Korean fuse, the circuit of the present invention is designed to be applicable thereto.

This circuit part is broadly divided into an intermediate frequency amplifier 200 and an envelope detector 300.

The intermediate frequency amplifier 200 includes an amplifying transistor Q 1 and an accessory circuit thereof.

The modulation signal of the intermediate frequency through the capacitor C 1 is applied to the base of the transistor Q 1. On the other hand, the input power is divided by the resistor R 1 and the resistor R 2 and applied to the base of the transistor Q 1 as a bias power source.

Resistor R 4 is a resistor for stabilizing the bias of the transistor Q 1.

The following equation is applied to obtain the amplification gain of the amplifier using the transistor Q 1.

Gain = (-β × (R 3 // R 5) ÷ (rπ)

In this case, β denotes a current gain of the transistor Q 1, and rπ denotes an equivalent AC resistance between the base emitters of the transistor Q 1.

The intermediate frequency amplifier using the above-described transistor amplifier experimentally obtained about 100 gains when the use frequency f = 2 MHz. The input level of the intermediate frequency signal input at this time was applied at a voltage of 150 mV (p-p), and the input current value at that time was about 7 mA.

On the other hand, as the bias condition, when the power supply voltage Vcc was 30 V, an optimum bias condition was obtained by flowing a current bias of 5 mA at a voltage of 15 V, which is the intermediate voltage.

In addition, the envelope detector 300 is formed using a resistor R 5, a resistor R 6, a diode D 1, and a capacitor C 4. The frequency modulated signal waveform is detected via the diode D 1 and the envelope waveform whose amplitude is changed.

In this case, the time constant determined by the resistor R 6 and the capacitor C 4 is preferably set to be sufficiently larger than one period of the input voltage of the intermediate frequency.

Since such an envelope detector has the same configuration as a detector for detecting a normal frequency modulated signal, a detailed description of its operation will be omitted.

In one embodiment, the intermediate frequency amplifying transistor amplifying circuit of the present invention may be formed by connecting the envelope detector to the rear end thereof integrally to reduce the spatial size thereof.

According to the configuration and operation of the present invention as described above, the intermediate frequency amplification transistor amplifier circuit of the fuse receiver of the present invention, the effect that the excellent amplification characteristics are exhibited in the intermediate frequency band used in the Korean fuse.

In addition, the intermediate frequency amplification transistor amplifying circuit of the fuse receiver of the present invention provides an effect that can be made compact in size to be suitable for use in fuses as compared with the prior art.

Although the present invention has been illustrated and described in connection with certain preferred embodiments, the present invention may be variously modified and changed without departing from the spirit or the field of the present invention provided by the following utility model registration claims. Those skilled in the art will readily recognize that there is a.

Claims (2)

A medium frequency amplifier for amplifying an intermediate frequency signal generated through a frequency conversion circuit, which is used in a receiver of a shell fuse, the capacitor C 1 for bypassing an input intermediate frequency signal and applying it to a transistor amplifier, An input signal through the capacitor C 1 is applied to its base, and a power supply voltage Vcc is applied to the collector via a resistor R 3, and a power supply voltage Vcc is applied to the transistor. Two resistors R 1 and R 2 that divide the voltage to bias the base of Q 1), and a resistor R 4 connected between the emitter and ground of the transistor Q 1 to stabilize the bias. ), A capacitor C 2 connected in parallel with the resistor R 4 to bypass the high frequency signal, and a signal of the intermediate frequency amplified by the transistor Q 1 to output the signal. It is connected to the intermediate frequency amplifier formed amplification transistor of the fuse receiver circuit, characterized in a capacitor (C 3) for outputting only the high-frequency signal. The fuse receiver according to claim 1, wherein the intermediate frequency amplifying transistor amplifying circuit is an amplifying circuit comprising an envelope detector composed of a diode D 1, a resistor R 6, and a capacitor C 4. Transistor amplifier circuit for intermediate frequency amplification.