KR930008193Y1 - Wireless microphone - Google Patents

Abstract

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Description

Wireless microphone

1 is a block diagram of a wireless microphone according to the present invention.

2 is a detailed circuit diagram of FIG.

* Explanation of symbols for main parts of the drawings

10: voice input means 20: voice amplification means

30: frequency modulation means 40: amplification means

50: high frequency generating means 60: antenna

70: power switch means 80: PLL

VR1: Volume variable resistor EMC: Microphone

The present invention relates to a wireless microphone, and more particularly to a wireless microphone of a multiple transmission and reception method.

Wireless microphones have recently been introduced to improve the inconvenience of wired microphones.

Wireless microphones are easier to use than wired microphones because they do not require wires to connect to the amplifier. However, the transmission frequency is fixed to a single frequency by a conventional wireless microphone, in which FM signals are transmitted by FM modulation.

Therefore, it could not be used unless the transmit frequency of the microphone and the receive frequency band of the amplifier match.

In addition, the conventional wireless microphone has only a ON / OFF switch function, so that only the ON state is kept in use, there is a problem that noise is transmitted or power is generated. When such noise and power are received and amplified or generated by the receiving amplifier, there is a problem that the user should always pay attention not to generate such noise due to very unpleasant noise generation.

An object of the present invention is to provide a wireless microphone with a multi-frequency transmission method and a standby function in order to solve the problems of the prior art as described above.

In order to achieve the above object, the present invention provides voice amplification means for amplifying the voice signal for converting voice into a voice signal which is an electrical signal; Frequency discriminating means for frequency discriminating the amplified speech signal; An antenna for transmitting the generated high frequency signal amplifying the frequency modulated signal to the air; And a power switch means for supplying a power supply voltage to the other means except for the voice input means in the standby state, and supplying a power voltage to the voice input means in the operating state.

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

1 shows a block diagram of a wireless microphone according to the present invention. In FIG. 1, 10 is a voice input means, 20 is a voice amplification means, 30 is a frequency modulation means, 40 is an amplification means, 50 is a high frequency generating means, 60 is an antenna, 70 is a power switch means, 80 is a PLL, and ECM It is a microphone and VR1 is a variable resistor for volume.

2 is a detailed circuit diagram of FIG. 2 shows an exemplary embodiment in which the voice amplifying means 20, the frequency modulating means 30, and the amplifying means 40 are formed using the MC 2833 (which is an FM modulation integrated circuit manufactured by Motorola).

In FIG. 2, the voice input means 10 receives the power supply voltage, that is, the output voltage B ⁺ of the battery, through the first switch SW1 of the power switch means 70 and receives B ⁺ through the resistor R5. The voltage is divided by the resistors R6 and R10 and supplied to the microphone ECM. The capacitor C16 is for removing power supply noise.

Therefore, when the power supply voltage is supplied to the microphone (ECM) through SW1, the voice is converted into an electrical voice signal, and the converted voice signal is input to the voice amplification means 20 through the coupling capacitor C6. The voice amplifying means 20, the frequency modulating means 30, and the amplifying means 40 are constituted by the FM modulation integrated circuit IC1. That is, the voice amplifying means 20 is an input amplifying circuit for amplifying the input signal supplied to the frequency modulating means 30, and the amplifying means 40 amplifies and outputs the frequency modulated signal from the frequency modulating means 30. Output amplifier circuit.

That is, the voice signal is input to pin 5 of IC1 via resistor R4 and amplified by microphone amplifier AMP and resistor R2.

The amplification gain (Av) is as follows.

The silver input impedance is then output through pin 4 of IC1 and supplied to capacitors C4 and C5 via resistor R3. The voice amplification signal is supplied to the frequency modulation means 30 via the variable resistor VR1 for volume connected in parallel with the capacitor C4.

The negative amplification signal through the coupling capacitor (C3) and resistor (R1) is supplied to the internal reactance block (X) through pin 3 of IC1, and the output of the block (X) is connected in series through pin 1 of IC1. It is supplied to the oscillation block OSC via L1) and the condenser C1. The oscillation signal generated by the oscillation block OSC is input to the 13-buffer via the coupling capacitor 19 through pin 14 and is supplied to the base of the internal transistor Q1. A frequency modulated signal is output through a history resonant circuit of a capacitor C7 and an inductance L3 connected to pin 11. The modulated signal is transmitted to the amplifier circuit 40 by inductive coupling of inductance L3 and L2 and supplied to the base of the internal transistor Q2 through pin 8 of IC1. The modulated signal amplified through the parallel resonant circuit of the primary coil of the capacitor 20 and the output transformer T connected to the pin 9 is supplied to the high frequency generating means 50. In the high frequency generating means 50, the modulation signal induced in the secondary coil of the output transformer T is supplied to the base of the transistor Q3 through the coupling capacitor C9, and at the same time through the phase loop PLL 80. Supply to pin 15 of IC1. Therefore, the frequency of the reference oscillation signal supplied from the PLL 80 is changed according to the variation of the audio signal output to pin 1 through the reactance block X, thereby generating a frequency modulated signal.

The high frequency generating means 50 connects the signal supplied to the base to the transistor Q3 in parallel connection of the capacitor C11 and the inductance L4, and the parallel connection of the capacitor C12, the capacitor C13, and the inductance L5. Frequency is multiplied through a series-parallel resonant circuit to generate a high frequency signal. By varying the frequency multiplier by varying the value of inductance L5, the multiplexing frequency can be set by varying the frequency of the high frequency signal induced by the antenna 60.

The antenna 60 transmits a high frequency signal to the air through an antenna circuit composed of inductances L6, L7 and L8 coupled to the inductance L5 of the high frequency generator 50 and the capacitors C16 to C19.

Reference numerals C8, C14, C21, and C22 are power supply noise eliminating capacitors, and R11, R12, R14, and R13 are power supply pullup resistors. C2, C17, C18, C12, C10, and C7 are noise canceling capacitors, and R9 is a pulldown resistor.

Referring to the effect of the present invention configured as described above are as follows.

First, when the second switch SW2 of the power switch means 70 is turned on, the power supply voltage B ⁺ is not supplied from the power source to the integrated circuit IC1 and the high frequency generating means 50, thereby becoming a standby state. At this time, since the power supply voltage B ⁺ is not supplied to the voice input means 10, no voice is input through the microphone ECM. Therefore, in the standby state, the transmission of the voice signal is blocked, so that unnecessary noise is amplified by the receiving amplifier and is not output.

Subsequently, when the first switch SW1 is turned on, the power input voltage B ⁺ is supplied to the voice input means 10, so that the voice is input as a voice signal through the microphone ECM, and the power supply voltage B ⁺ is already supplied. The voice amplification means 20, the frequency conversion means 30, the amplification means 40, and the high frequency generating means 50 is sent out.

By adjusting the inductance (L5) value of the high frequency generating means according to the receiving frequency band of the receiving amplifier, it is possible to set multiple transmission frequencies so that compatibility is maintained and it is very convenient to use the FM radio receiver as the receiving amplifier.

Claims (1)

Voice input means for converting and inputting voice into an electrical voice signal; Voice amplification means connected to the voice input means to amplify a voice signal; Frequency modulating means connected to said voice amplifying means for generating a modulated signal frequency modulated according to the amplified voice signal; Amplifying means connected to said frequency modulating means for amplifying a modulated signal; High frequency generating means connected to said amplifying means for supplying a reference frequency signal which is costume-locked to a modulated signal to said frequency modulating means and multiplying the modulated signal according to a given frequency multiplier to produce a high frequency signal; An antenna connected to the high frequency generating means to transmit a high frequency signal to the air; And a power switch means for supplying a power voltage to the other means except for the voice input means in the standby state and a power voltage to the respective means in the operating state.