JP3150933U - Audio FM modulation amplifier - Google Patents

Abstract

An audio FM modulation amplifier capable of reproducing a sound with good sensitivity by improving the reproduction degree of a bass signal. A block in which an audible frequency range is sequentially divided so as to correspond to a plurality of wavelength ranges is connected in parallel between an audio signal input terminal and an amplifier, and each block has an input voltage corresponding to the input audio signal. And a comparator that compares the detection reference voltages divided to correspond to a plurality of wavelength ranges, and an FM that is connected to the comparator and that modulates the input audio signal and the fundamental wave from the fundamental wave oscillation circuit. A modulation circuit and an FV conversion circuit connected to the FM modulation circuit and FV-converting the FM modulation signal are compared with each other by comparing the input voltage corresponding to the input audio signal and the detection reference voltage with a comparator. Only in the case of an input audio signal, this input audio signal and the fundamental wave from the fundamental wave oscillation circuit are FM-modulated, and the FM modulation signal is FV converted and output to an amplifier. Oh FM modulation amplifier. [Selection] Figure 2

Description

  The present invention relates to an audio FM modulation amplifier having an improved circuit for improving sound quality.

  The intensity of sound is such that the fundamental wave of a waveform is modulated and overlapped and vibrates in a complicated manner, and generally the amplitude of an audible range of 16 Hz to 20000 Hz is modulated. Audio equipment that uses conventional audio signals, especially in the case of small radios, can be amplified when amplified by an amplifier, but sounds in the low frequency range cannot be reproduced clearly, and the sound becomes turbid due to resonance. There is a problem that cracks occur.

  In view of this point, the inventor of the present case, as a result of intensive research and development, has proposed a basic technique (hereinafter referred to as “basic technique”) related to an audio modulation amplifier as a utility model registration No. 3135265. .

  In this basic technology, a plurality of blocks in which the audible frequency range is divided in order to correspond to a plurality of wavelength ranges are connected in parallel between the input terminal of the audio signal and the amplifier, and each block corresponds to the input audio signal. A comparator that compares the detected input voltage with the detection reference voltages divided to correspond to a plurality of wavelength ranges, and is connected to the comparator, and the input audio signal and the fundamental wave from the fundamental wave oscillation circuit are FM An FM modulation circuit that modulates the input audio signal and a detection reference voltage according to the input audio signal are compared by a comparator. This is an audio FM modulation amplifier so that the fundamental wave from is FM-modulated and output to the amplifier.

  By this basic technology disclosure, the audible frequency range is divided into a plurality of blocks so as to sequentially correspond to a plurality of wavelength ranges, and the detection reference voltage corresponding to each frequency is sequentially switched and input by a comparator in each block. The input voltage corresponding to the audio signal is compared with the detection reference voltage, and the fundamental wave corresponding to the frequency is output from the fundamental wave oscillation circuit and FM modulated only when the input audio signal has the corresponding level, so the sensitivity is rich. Significant technology that can be reproduced with high sound quality and clear sound will be provided.

  After disclosing the above basic technology, the inventor of the present invention has further studied earnestly, and as a result, has further proposed improved technology related to the audio modulation amplifier. This improved technique is disclosed as Utility Model Registration No. 3140433. However, the detection reference voltage used for the comparator has a digital staircase shape, and the voltage output jumps by the frequency of the clock pulse. The detection reference voltage generation circuit is an electric circuit having a comparator that compares the voltage of the input audio signal with the detection reference voltage, and the detection reference voltage is connected to the digital-analog converter by a resistor Rn1. ~ Rnm (where n and m are integers) connected in parallel, a counter for counting pulses oscillated from the clock pulse oscillation circuit is connected to this digital-analog converter, and a counter for counting pulses from the clock pulse oscillation circuit Then, the voltage obtained by sequentially switching the resistors Rn1 to Rnm is used as the bias voltage of the first oscillation circuit, and the first The voltage obtained from the oscillation circuit is characterized in that it is assumed that has been converted by the FV converting circuit.

  As described above, the inventor of the present invention has contributed to the development of the technology relating to the audio modulation amplifier, but now, he proposes a new technology.

Utility Model Registration No. 3135265 Utility Model Registration No. 3144403

  An object of the present invention is to provide an audio FM modulation amplifier that can reproduce a sound quality with high sensitivity by improving the reproduction degree of a bass signal.

  That is, according to the present invention, blocks in which an audible frequency range is sequentially divided to correspond to a plurality of wavelength ranges are connected in parallel between an audio signal input terminal and an amplifier, and each block corresponds to an input audio signal. A comparator that compares the input voltage and the detection reference voltage divided to correspond to a plurality of wavelength ranges, and is connected to this comparator, and the input audio signal and the fundamental wave from the fundamental wave oscillation circuit are FM modulated. And an FV conversion circuit that is connected to the FM modulation circuit and performs FV conversion on the FM modulation signal. The input voltage corresponding to the input audio signal is compared with the detection reference voltage by a comparator, and Only when the input audio signal is level, the input audio signal and the fundamental wave from the fundamental wave oscillation circuit are FM-modulated, and the FM modulation signal is FV converted and output to the amplifier. It is an audio FM modulation amplifier.

  As in the present invention, when an input audio signal (FM modulated signal) FM-modulated by a fundamental wave is FV converted (frequency voltage converted), a voltage that is directly proportional to the frequency is output, and the output voltage is shifted by the frequency of the fundamental wave. Therefore, it is possible to output a bass range when amplified by an amplifier. Therefore, it is possible to provide an audio FM modulation amplifier that can reproduce sound with good sensitivity by improving the reproduction degree of the bass signal.

  Also, the invention is characterized in that the block is divided into three blocks, a low-frequency block, a mid-frequency block, and a high-frequency block, so that the audible frequency range corresponds to the three wavelength ranges sequentially. This is an FM modulation amplifier. Further, according to the present invention, each fundamental wave oscillation circuit in each block oscillates a fundamental wave having a constant frequency, and the frequency of the fundamental wave in the middle range is higher than the frequency of the fundamental wave in the low frequency block. The audio FM modulation amplifier is characterized in that the frequency of the fundamental wave of the high-frequency block is larger than the frequency of the fundamental wave of the mid-frequency block.

  The present invention can provide an audio FM modulation amplifier that can reproduce sound with good sensitivity by improving the reproduction degree of a bass signal.

Circuit diagram of an FM modulation amplifier according to an embodiment of the present invention 1 is a circuit diagram showing the configuration of each block in FIG. Explanatory drawing which shows the voltage change of the input audio | voice signal of this invention Explanatory drawing showing the output audio signal etc. of the present invention A circuit diagram showing another embodiment of each block shown in FIG.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS. FIG. 1 shows a circuit of an audio FM modulation amplifier. Reference numeral 1 denotes an input terminal to which a sound signal from a tuner such as a radio, a tape recorder, audio such as CD or MO is input. A digital-analog converter 2 is connected to the input terminal 1 and converts a digital signal such as CD or MO into an analog signal.

  Reference numeral 3 denotes an amplifier, and three blocks B1 to B3 are connected in parallel between the amplifier 3, the input terminal 1 and the digital-analog converter 2, and each block B1 to B3 has a clock pulse. The oscillation circuit 5 is connected in parallel.

  As shown in FIG. 2, the block B1 is provided with an input terminal 1 or an input terminal 6 for an analog audio signal from the digital-analog converter 2, and a comparator 7 for comparing the voltages connected thereto is provided. Yes. The input audio voltage from the input terminal 6 is connected to the + side of the comparator 7, the resistor R 10 is connected to the − side, and resistors R 11 to R 110 are connected in parallel between the resistor R 10 and the digital-analog converter 8. It is connected.

  The digital-analog converter 8 is connected to the clock pulse oscillation circuit 5 via a counter 9, and the pulses oscillated from the clock pulse oscillation circuit 5 are counted by the counter 9 and connected to the digital-analog converter 8. The resistors R11 to R110 are sequentially switched. The clock pulse oscillation circuit 5 is common to the blocks B1 to B3.

  The input terminal 6 is connected to the first electronic relay 10 via the digital-analog converter 8. The first electronic relay 10 is connected to the output side of the comparator 7 via an inverter 11 constituted by a NAND gate. The first electronic relay 10 is connected to the output terminal 13 to the amplifier 3 via the FM modulation circuit 12.

  Reference numeral 15 denotes a fundamental wave oscillation circuit that oscillates a fundamental wave having a constant frequency, and is connected to the FM modulation circuit 12 via a second electronic relay 16. The frequency of the fundamental wave oscillated from the fundamental wave oscillation circuit 15 is f1 in the block B1, f2 in the block B2, f3 in the block B3, and f1 <f2 <f3. Each frequency of the fundamental wave oscillation circuit is increased stepwise according to the number of blocks to be divided.

  The second electronic relay 16 is connected to the inverter 11. The output of the FM modulation circuit 12 is connected to the FV conversion circuit 17.

  In the block B2, as shown in FIG. 2, a resistor R20 is connected to the negative side of the comparator 7, and resistors R21 to R210 are connected in parallel between the resistor R20 and the digital-analog converter 8. .

  Similarly, in the block B3, as shown in FIG. 2, a resistor R30 is connected to the minus side of the comparator 7, and further, resistors R31 to R310 are connected in parallel between the resistor R30 and the digital-analog converter 8. Has been.

  As shown in FIG. 2, each FV conversion circuit 17 in each block B1, B2, B3 is connected and connected to an amplifier.

  When an analog input audio signal from a tuner such as a radio or a tape recorder is input from the input terminal 1, the audio FM modulation amplifier having the above-described configuration is connected to the comparator 7 from the input terminal 6 of each block B1 to B3. Input to the + side. Further, when a digital input audio signal from an audio device such as a CD or MO is input from the input terminal 1, it is converted into an analog signal by the digital-analog converter 2, and from the input terminal 6 of each of the blocks B1 to B3. Input to the + side of the comparator 7.

  Blocks B1 to B3 sequentially divide the audible frequency range of 16 Hz to 20000 Hz so as to correspond to a plurality of wavelength ranges, for example, block B1 is responsible for the low frequency range of 16 Hz to 99 Hz, and block 2 is the intermediate frequency range of 100 Hz to 400 Hz The part 3 is responsible for the high frequency range part of 400 Hz to 20000 Hz. The number to be divided is not particularly limited.

  In the block B1, the resistors R11 to R110 are sequentially switched by the counter 9 that counts the pulses from the clock pulse oscillation circuit 5 to switch to the detection reference voltage corresponding to the resistor R10 + Σ (resistors R11 to R110). Further, when a reset circuit is formed from the digital-analog converter 8 to the counter 9 and the counter 9 measures “1” to “10”, the counter 9 is reset and repeatedly measures “1” to “10” again. The resistors R11 to R110 are sequentially switched.

  Similarly, also in the block B2, the counter 9 sequentially switches the resistors R21 to R210 and switches to the detection reference voltage corresponding to R20 + Σ (resistors R21 to R210).

  Similarly, also in the block B3, the counter 9 sequentially switches the resistors R31 to R310 to switch to the detection reference voltage corresponding to R30 + Σ (resistors R31 to R310).

  In the comparator 7, the input audio signal from the input terminal 6 is input to the + side, but the frequency is generally proportional to the voltage, so the input voltage corresponding to the input audio signal corresponds to the frequency from the-side in advance. The signal is output to the inverter 11 when the input voltage is within the range of the detection reference voltage, and the signal is not output when the input voltage is not input. For example, assuming that the frequency of the input audio signal is 300 Hz, if the block B1 is responsible for the part of 16 Hz to 99 Hz and the block B2 is responsible for the part of 100 Hz to 400 Hz, the signal is output from the block 1 because it is in the range of the block B2. Not.

  When the input voltage falls within the range of the detection reference voltage, a signal is output to the inverter 11, where it is inverted and a signal from “0” to “1” is output, and the first electronic relay 10 and the second electronic relay 10 are output. The electronic relay 16 is turned on. When the first electronic relay 10 is turned on, the input audio signal from the input terminal 6 is output to the FM modulation circuit 12 and the fundamental wave is output from the fundamental wave oscillation circuit 15 to the FM modulation circuit 12.

  The FM modulation circuit 12 outputs to the FV conversion circuit 17 an FM modulation signal obtained by changing the frequency of the fundamental wave by a value proportional to the amplitude of the frequency of the input audio signal. The FM modulation signal is converted into a voltage that is directly proportional to the frequency by an FV conversion circuit 17 (frequency voltage converter) connected to the output side of the FM modulation circuit 12, and then the converted voltage is sent to a speaker via an amplifier. Is output.

That is, as shown in FIG. 3A, when the input voltage falls within the range of the detection reference voltage of the block B1 that is responsible for the low frequency (av, a> 0), the input audio signal is the fundamental wave generation circuit. Since the FM modulation circuit 17 performs modulation within a predetermined range based on the 15 fundamental waves (f ₀ ) (f ₀ ≦ f ≦ f ₁ ), the output voltage passed through the FV conversion circuit 17 is f = f ₀ . Assuming V ₀ , V ₀ + ΔV ₀ when f = f ₁ . Thus, the output voltage shifts higher by V ₀ corresponding to f ₀ .

Also, as shown in FIG. 3B, when the input voltage is in the range of the detection reference voltage of the block B2 that handles the middle range (a ≦ v ≦ b), the input audio signal is a fundamental wave generating circuit. Since the FM modulation circuit 17 performs modulation within a predetermined range based on the 15 fundamental waves (f ₁ ) (f ₁ ≦ f ≦ f ₂ ), the output voltage passed through the FV conversion circuit is V when f = f ₁ . _1, the _{V 1} + [Delta] V ₁ when f = _{f 2.} Thus, the output voltage is shifted higher by V ₁ corresponding to f ₁ .

Similarly, as shown in FIG. 3C, when the input voltage falls within the range of the detection reference voltage of the block B3 that handles the high frequency (b ≦ v ≦ c), the fundamental of the fundamental wave generation circuit 15 Since the FM modulation circuit 17 performs modulation within a predetermined range based on the wave (f ₂ ) (f ₂ ≦ f ≦ f ₃ ), the output voltage passed through the FV conversion circuit is V ₂ when f = f ₂ . , V ₂ + ΔV ₂ when f = f ₃ . That is, the output voltage shifts higher by V ₁ corresponding to f ₂ .

Thus, the voltage shifts higher by the frequency of the fundamental wave oscillation circuit (low frequency is f ₀ , middle frequency is f ₁ , and high frequency is f ₂ ), so that when amplified by an amplifier, the low frequency is output. Can do. The voltage is shifted high and output in the middle and high bands as well. Therefore, the reproduction degree of the bass signal is improved, and the reproduction of the sound quality with high sensitivity becomes possible. Since the frequency is continuously modulated by the FM modulation circuit, natural sound can be reproduced when a digital sound source such as a CD is converted into an analog signal by digital-analog conversion.

  FIG. 4 shows the audio signal waveforms of the low frequency (A), middle frequency (B), and high frequency (C) described above, and the output audio waveform combining the signal waveforms.

  FIG. 5 shows another embodiment of the circuit in the block of FIG. 2 (inside the broken line) (common to all blocks, not limited to the block B1). The circuit of FIG. 5 is an electric circuit having a comparator that compares the voltage of an input audio signal with a detection reference voltage, and the detection reference voltage is supplied to resistors Rn1 to Rnm (however, n, m) in a digital-analog converter. Are connected in parallel, and a counter that counts the pulses oscillated from the clock pulse oscillation circuit is connected to the digital-analog converter, and the resistors Rn1 to Rnm are connected to the counter that counts the pulses from the clock pulse oscillation circuit. A detection reference voltage generating circuit characterized in that a voltage obtained by sequentially switching is used as a bias voltage of the first oscillation circuit, and a voltage obtained from the first oscillation circuit is converted by an FV conversion circuit. is there.

  Further, the circuit of FIG. 5 is obtained from 0 to 1 / 2π obtained through a diode from the second oscillation circuit that is synchronized with the pulse oscillated from the clock pulse oscillation circuit after being converted by the FV conversion circuit in the detection reference voltage generation circuit. This is a detection reference voltage generation circuit characterized by continuously adding the sine wave voltage. 5 is provided with a comparator for comparing the voltage of the analog input audio signal with the detection reference voltage, and an input terminal for inputting an audio voltage is connected to the + side, and the circuit side of FIG. Only when an input audio signal corresponding to the detection reference voltage is input by connecting the output of the detection reference voltage according to item 2 and comparing the input voltage corresponding to the input audio signal with the detection reference voltage by a comparator. An electric circuit characterized by outputting an audio voltage.

  In this circuit, the voltage range can be determined by various circuits by biasing the frequency of the first oscillation circuit and modulating the frequency. According to this, since a constant voltage is secured at the natural frequency of the first oscillation circuit, for example, a low-frequency sound has a low voltage and is difficult to reproduce, but FM modulation is performed from that time by the secured voltage. An additional voltage is generated. For example, even when amplified from 0.1V, the degree of reproduction is low, but when amplified from 1V, reproduction is easy.

DESCRIPTION OF SYMBOLS 1 Input terminal 2 Digital-analog converter 3 Amplifier B1-B3 block 5 Clock pulse oscillation circuit 6 Input terminal 7 Comparator 8 Digital-analog converter 9 Counter 10 1st electronic relay 11 Inverter 12 FM modulation circuit 13 Output terminal 15 Fundamental oscillation circuit
16 Second electronic relay
17 FV conversion circuit

Claims (3)

  Between the audio signal input terminal and the amplifier, blocks in which the audible frequency range is sequentially divided so as to correspond to multiple wavelength ranges are connected in parallel, and each block has an input voltage and multiple wavelengths according to the input audio signal. A comparator that compares detection reference voltages that are divided so as to correspond to a region; an FM modulation circuit that is connected to the comparator and performs FM modulation on an input audio signal and a fundamental wave from a fundamental wave oscillation circuit; An FV conversion circuit connected to the FM modulation circuit and FV-converting the FM modulation signal is compared with the input voltage corresponding to the input audio signal and the detection reference voltage by the comparator, and the input audio signal of the corresponding level is compared. Only when the input audio signal and the fundamental wave from the fundamental wave oscillation circuit are FM-modulated, the FM modulation signal is FV-converted and output to an amplifier. Audio FM modulation amplifier.   2. The audio FM modulation amplifier according to claim 1, wherein the block is divided into a low-frequency block, a mid-frequency block, and a high-frequency block so that an audible frequency range sequentially corresponds to three wavelength ranges. . Each fundamental wave oscillation circuit in each block oscillates a fundamental wave having a constant frequency, and the frequency of the fundamental wave in the middle band is larger than the frequency of the fundamental wave in the low band block. The audio FM modulation amplifier according to claim 2, wherein the frequency of the fundamental wave of the high-frequency block is larger than the frequency of the fundamental wave of the above.

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