KR0162273B1 - Remote control receiver - Google Patents

Abstract

The present invention relates to a receiver used for remote control of the UHF band, and to solve this problem, a remote having a first and second crystal oscillation elements providing different oscillation frequencies and an RF filter for filtering RF frequencies received from an antenna. A control receiving device comprising: oscillating and multiplying means for oscillating as a third harmonic of an oscillating frequency by a first quartz crystal, and for multiplying a sinusoidal wave of the oscillated frequency; A first intermediate frequency calculating means for mixing the received and filtered frequencies to calculate a first intermediate frequency, and a second intermediate frequency for mixing the oscillation frequencies of the first intermediate frequency calculating means and the second quartz crystal vibrating element. Pre-modulation before modulation from the second intermediate frequency calculating means and the second intermediate frequency output by the second intermediate frequency calculating means. It made of a conversion, and output means for outputting the detection.

Description

Receiver for remote control

1 is a block diagram of a remote control receiver according to the present invention.

2 is a circuit diagram of a receiver for remote control according to the example of FIG.

* Explanation of symbols for main parts of the drawings

10: first local oscillator 20: RF filter

30: RF amplification unit 40: first mixing unit

50: first intermediate frequency filter 60: first intermediate frequency amplifier

70: second intermediate frequency filter 80: FM detector

90: converter 100: FM receiver IC

R1-R21: Resistor C1-C30: Capacitor

L1-L10: Coil (Inductance) VD1: Variable Capacitance Diode

X1, X2: Crystal Oscillator VC1: Variable Capacitor

The present invention relates to a super heterodyne frequency shift keying (FSK) receiver used for remote control of an ultra high frequency (UHF) band.

In general, in order to perform remote remote control with a transmitter having limited transmission power, the sensitivity of the receiver needs to be increased to the maximum. For this purpose, a super heterodyne receiver having multiple local oscillation frequencies is generally used. This type of receiver has high reception sensitivity because of good attenuation of the image signal and good selectivity.

In addition, in order to reduce the influence of external noise in a remote control that requires high reliability, the FSK method for transmitting digital information by a frequency modulation (FM) method is generally used.

In addition, the design of superheterodyne narrow-band receivers for remote control is indispensable, as the type of verification (checking) system for remote control devices is limited by the transmitter output and occupied bandwidth.

However, in order to implement such a receiver, a local oscillator circuit, multiple RF and IF amplifier stages must be configured, which makes the circuit complicated and requires a large number of high frequency transformers at the crystal oscillator, crystal filter, RF, and IF stage. This is complicated to make and expensive receivers.

In addition, the local oscillator circuit basically determines a reception frequency. In order to receive a signal from a transmitter having a narrow bandwidth, the frequency oscillator must be stable, and thus a crystal oscillator is used. In order to maximize the transfer of power between the amplifier and the amplifier, the impedance matching should be well done, and usually using a high frequency transformer.

These transformers act as narrowband filters at the same time, which improves the signal-to-noise ratio at each stage, resulting in a high receiver sensitivity.

To achieve this band, the high-frequency transformer must be able to vary its inductance value and have a high Q value. In addition, using multiple transformers in series or in parallel requires a complex process that requires fine tuning of each transformer to complete the assembled receiver.

Accordingly, the present invention has been made to solve the above disadvantages, an object of the present invention is to provide a receiver for remote control to simplify the complicated fine adjustment using a superheterodyne scheme.

According to the present invention for achieving the above object, in the remote control receiver having an RF filter for filtering the RF frequency received from the first and second crystal oscillation element and the antenna providing different oscillation frequency, Oscillation and multiplication means for oscillating as a third harmonic of an oscillation frequency by a single crystal oscillator and multiplying a sine wave of this oscillation frequency; First intermediate frequency calculating means for calculating a first intermediate frequency by mixing the frequency applied by the oscillation and multiplication means and the frequency received and filtered from the antenna; Second intermediate frequency calculating means for calculating a second intermediate frequency by mixing the oscillation frequencies of the first intermediate frequency calculating means and the second quartz crystal vibrating element; And converting and outputting means for detecting and outputting information before the modulation from the second intermediate frequency output by the second intermediate frequency calculating means.

Hereinafter, embodiments of the present invention will be described in detail with reference to the illustrated drawings. FIG. 1 is a block diagram of a remote control receiver according to the present invention, and FIG. 2 is a circuit diagram of a remote control receiver according to an exemplary embodiment of FIG.

Referring to FIGS. 1 and 2, the first local oscillator 10 has a sine wave oscillated by 3rd overtone harmonics in the first tuning circuit [(C5, L3), (C8). , L4)], and is multiplied three times by the second tuning circuits C10 and L5 to perform local oscillation of the UHF band, and then provide it to the first mixing section 40 described later. The first local oscillator 10 includes a variable capacitance capacitor VC1, a first quartz crystal oscillator X1, a filter and coupling capacitor C1-C10, a voltage divider resistor R1-R5, and a transistor ( Q1-Q2) and the like.

The RF filter 20 is configured to filter the frequency received from the antenna 1 and provide the RF amplifier 30 to be described later.

The RF amplifier 30 is configured to amplify the RF frequency filtered from the RF filter 20 to be provided to the first mixing unit 40 to be described later, the RF amplifier 30 is a filter and coupling capacitor ( C12, C13, C16, and C19, the voltage divider resistors R6 and R8, and the amplifying transistor Q3.

The first mixing unit 40 is configured to mix the oscillation frequency output from the first local oscillation unit 10 and the frequency output from the RF amplifier 30 to be provided to the first intermediate frequency filter unit 50 described later. The first mixing part 40 includes filter and coupling capacitors C15 and C17, voltage dividing resistors R9, R10 and R11, and a transistor Q4.

The first intermediate frequency filter unit 50 is configured to calculate the difference frequency, that is, the first intermediate frequency, from the frequencies mixed by the first mixing unit 40 and to provide the first intermediate frequency amplifier 60 to be described later. do.

The first intermediate frequency amplification unit 60 is configured to amplify the first intermediate frequency calculated from the first intermediate frequency filter unit 50 to be provided to the RF terminal 16 of the FM receiver IC 100 described later. The first intermediate frequency amplifier 60 includes filter and coupling capacitors C17 and C18, resistors R12 and R13, and a transistor Q5.

The FM receiver IC 100 is a well-known element, and since a second local oscillation circuit and a second mixing part are built in an internal circuit terminal, the oscillation frequency of the second crystal oscillator X2 is set to the FM receiver IC 100. It is provided through the terminals (1, 2).

The second mixing unit in the FM receiver IC 100 mixes the first intermediate frequency of the first intermediate frequency amplifying unit 60 and the oscillation frequency from the second quartz crystal oscillator X2 and then the terminal of the FM receiver IC 100. It is configured to be provided to the second intermediate frequency filter unit 70 connected to (3, 4, 5).

The second intermediate frequency filter 70 calculates the difference frequency, that is, the second intermediate frequency, from the frequencies mixed by the second mixing unit, and transmits the FM through the terminals 9, 10, and 11 of the FM receiver IC 100. It is configured to be provided to the detection unit 80.

The FM detection unit 80 detects the information before the modulation from the second intermediate frequency calculated by the second intermediate frequency filter unit 70, and will be described later through the terminals 6, 7, and 9 of the FM receiver IC 100. It is configured to be provided to the conversion unit 90, the FM detection unit 80 is composed of a capacitor (C29-C30), a resistor (R15), a coil L10 capable of fine adjustment.

The conversion unit 90 is connected to the terminals 9, 10, 11, 12 of the FM receiver IC 100, and a low pass filter 92 for filtering the demodulated signal provided from the terminal 9 at low frequency, An integrated circuit stage 94 for integrating the demodulated signal filtered by the low pass filter 92 and a signal converted into a digital signal by the integrated circuit stage 94 through the terminal 14; It is configured to be.

In more detail, the low pass filter 92 of the conversion unit 90 is composed of condensers C24 and C25 and a resistor R18, and the integrating circuit stage 94 is filtered from the low pass filter 92. In order to convert this signal into a digital signal, it consists of a capacitor C23 and resistors R17 and R19.

Referring to Figure 2 the operation of the present invention configured as described in detail as follows.

First, power from the standby power supply terminal (+ V) is provided to each circuit terminal of the apparatus so that a frequency signal transmitted from a transmitter not shown can be provided.

Accordingly, the first local oscillator 10 oscillates from the crystal oscillator X1, and the sine wave oscillated into the third harmonic by the transistor Q1 is the first tuning circuit [ (C5, L3), (C8, L4)].

In addition, the frequency multiplied by 3 times is to multiply the frequency multiplied by 3 times by the transistor Q2 and the second tuning circuits C10 and L5 again to 3 times, which is to perform local oscillation of the UHF band. .

That is, the oscillated signal is provided to the base terminal of the transistor Q4 of the first mixing part 40. In this case, when there is a frequency reception from the antenna 1, the RF filter 20 filters only the UHF band received from the antenna 1 and then provides it to the RF amplifier 30.

In addition, the circuit is configured by using a coil and a condenser element having a fixed value instead of a resonance and impedance matching circuit using a high frequency transformer at the output terminals of the transistors Q1 and Q2.

Subsequently, the RF amplifying unit 30 amplifies the received signal with a fine (small) UHF band signal received from the RF filter 20, and then provides the amplified signal to the transistor Q4 of the first mixing unit 40. do. When the transistor Q3 of the RF amplifier 30 and the first mixing unit 40 are connected, impedance matching is implemented using only the coil L6 and the capacitor C19 instead of the high frequency wave.

The transistor Q4 of the first mixing unit 40 mixes the oscillation frequency output from the first local oscillation unit 10 and the frequency output from the RF amplifier 30 and then passes to the first intermediate frequency filter unit 50. The input matching of the transistor Q4 of the first mixing part 40 and the first intermediate frequency filter 50 is implemented only by the resistor C11, thereby reducing the volume of the device.

In detail, the high frequency transformer is not used in the coupling between the transistor Q4 and the transistor Q5, and the impedance matching between the transistor Q5 and the second mixing portion of the FM receiver IC 100 is generally used. Only R13) was used to carry out.

Subsequently, the first intermediate frequency filter unit 50 calculates a differential frequency, that is, a first intermediate frequency, from the frequencies mixed by the first mixing unit 40, thereby producing a transistor Q5 of the first intermediate frequency amplifier 60. ) Will be provided.

In this case, since the output impedance of the second intermediate frequency filter unit 70 is low because the first intermediate frequency filter unit 50 and the FM detector 80 are connected as the transistor Q5, the impedance of the input terminal of the transistor Q5 is low. Was combined at high.

For example, when the frequency output from the RF amplifier 30 is 90 MHz and the oscillation frequency output from the first local oscillator 10 is 100 MHz, the first intermediate frequency obtains the difference frequency of the two signals 10 MHz.

Subsequently, the first intermediate frequency amplifier 60 amplifies the first intermediate frequency calculated from the first intermediate frequency filter unit 50 by the amplifying transistor Q5 and then RF terminal of the FM receiver IC 100. (16).

The second mixing unit of the FM receiving IC 100 mixes the oscillation frequency from the second quartz crystal oscillator X2 and the first intermediate frequency of the first intermediate frequency amplifying unit 60, and then the terminal (3) of the FM receiving IC 100. It is provided to the second intermediate frequency filter unit 70 is connected to, 4,5.

The second intermediate frequency filter 70 calculates the difference frequency, that is, the second intermediate frequency, from the frequencies mixed by the second mixing unit, and transmits the FM through the terminals 6, 7, and 8 of the FM receiver IC 100. It is provided to the detection unit 80.

The FM detector 80 detects the information before the modulation from the second intermediate frequency calculated by the second intermediate frequency filter unit 70 and then provides it to the converter 90 through the terminal of the FM receiver IC 100. do.

The low pass filter 92 of the converter 90 low-pass filters the demodulated signal provided from the terminal 9 of the FM receiver IC 100 and then integrates the signal into the integrated circuit 94 of the converter 90. Is applied. The integrating circuit stage 94 integrates the signal filtered and demodulated by the low pass filter 92.

That is, the analog signal is converted by the integrating circuit stage 94 into a digital signal so that the received and modulated remote control signal is provided through the terminal 14 of the FM receiving IC 100. When the distortion value of the demodulated signal is 12db after passing through the filter CCITT, the reception sensitivity of the signal input to the 50Ω antenna is about -121 dBm.

The demodulated signal must then be converted to a digital signal for printing by a microprocessor (not shown). The implementation of this function is achieved by the terminal 10 of the filter amplifier (FM receiver IC 100) inside the FM receiver IC (100). 11) and the terminals 12 and 14 are used.

The demodulated signal output from the terminal 9 of the FM receiver IC 100 as described above is subjected to low-pass filtering by the resistors R18 and R25, and then the signal It is input to the integrating circuit 94 composed of 10 and 11 to be amplified and attenuated.

The preprocessed signal is applied to the terminal 12 of the FM receiver IC 100 of the gate having hysteresis, and the output signal is output as the final digital signal through the terminal 14.

As described above, the present invention adjusts only three points by the variable capacitor VC1 for fine adjustment of the first local oscillation frequency, the filter of the UHF band, and the detection coil L10 for FM demodulation. In addition, compared to the conventional superheterodyne receiver significantly reduced the adjustment point, the circuit is also simple, there is an advantage that the receiver is easy to assemble.

In addition, this invention is not limited to the said Example, A deformation | transformation is possible in the range which does not deviate from the technical summary of this application.

Claims (5)

In the remote control receiver having a first and second crystal oscillation element providing different oscillation frequency, an RF filter for filtering the RF frequency received from the antenna, and an RF amplifier for amplifying the filtered frequency of the RF filter, Oscillation and multiplication means for oscillating as a third harmonic of an oscillation frequency by said first quartz crystal and multiplying a sinusoidal wave of this oscillation frequency; First intermediate frequency calculating means for calculating a first intermediate frequency by mixing the frequency output by the oscillation and multiplication means and the frequency received and filtered from the antenna; Second intermediate frequency calculating means for calculating a second intermediate frequency by mixing the oscillation frequencies of the first intermediate frequency calculating means and the second quartz crystal vibrating element; And converting and outputting means for detecting and outputting the information before the modulation from the second intermediate frequency output by the second intermediate frequency calculating means. The receiver of claim 1, wherein the RF filter and the RF amplifying unit comprise a coil and a capacitor having a fixed value. The receiver of claim 1, wherein the first intermediate frequency calculating means comprises a first mixing unit 40, a first intermediate frequency filter 50, and a first intermediate frequency amplifier 60. . The receiver of claim 3, wherein an impedance matching is set as a resistance value between the first intermediate frequency filter 50, the first mixing unit 40, and the first intermediate frequency amplifier 60. . The integrated circuit of claim 1, wherein the converting and outputting means comprises: a low pass filter for low-pass filtering the demodulated signal, an integrating circuit stage for integrating the demodulated signal filtered by the low pass filter, and the integrating circuit stage And an output terminal for converting the digital signal into an output signal and outputting the digital signal.