JP2012242664A - Electronic musical instrument - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make performance easier.SOLUTION: A fixed frequency oscillation circuit 2 generates a fixed frequency electric signal showing a fixed-frequency wave having a frequency fixed. A variable frequency oscillation circuit 3 generates a variable-frequency electric signal showing a variable-frequency wave having a frequency varied on the basis of a floating capacity between a hand 12 and an antenna. A frequency difference circuit 5 generates a difference electric signal showing a difference frequency wave having a frequency which is the difference between the frequency of the fixed-frequency wave and that of the variable-frequency wave. A sound production circuit 6 generates a sound electric signal showing a sound waveform so that the frequency of the sound waveform is lower than the frequency of the difference frequency wave. Sound devices 7 and 8 generate sounds indicated by the sound waveform. In this case, an influence of variations in frequency of the fixed-frequency wave and the variable-frequency wave on a pitch of the sounds is small and adjustment of the fixed frequency oscillation circuit 2 and the variable frequency oscillation circuit 3 is unnecessary, so that a user can more easily play an electronic musical instrument.

Description

  The present invention relates to an electronic musical instrument, and more particularly to an electronic musical instrument that generates a musical tone having a pitch that changes based on a stray capacitance between a hand and an antenna.

  2. Description of the Related Art Electronic musical instruments that generate musical tones that change based on stray capacitance between a hand and an antenna are known. Theremin is exemplified as the electronic musical instrument (for example, see Non-Patent Document 1). As shown in FIG. 1, the electronic musical instrument 100 includes a fixed frequency oscillation circuit 102, a variable frequency oscillation circuit 103, a frequency difference circuit 105, an audio amplification device 107, and a speaker 108. The fixed frequency oscillation circuit 102 generates a fixed frequency electric signal when the electronic musical instrument 100 is activated. The fixed frequency electrical signal is formed from a wave whose voltage changes periodically with time. The wave has a constant frequency and is fixed at a fixed frequency. An example of the fixed frequency is 500 kHz.

  The variable frequency oscillation circuit 103 includes an antenna 111. The variable frequency oscillation circuit 103 generates a variable frequency electric signal when the electronic musical instrument 100 is activated. The variable frequency electrical signal is formed from a wave whose voltage changes periodically with time. The frequency of the wave is variable, and the frequency changes based on the stray capacitance between the player's hand 112 and the antenna 111. The frequency monotonously decreases with respect to the distance between the hand 112 and the antenna 111, and shows one frequency in the range of 496.8 kHz to 499.9 kHz.

  The frequency difference circuit 105 generates an audio electrical signal based on the fixed frequency electrical signal generated by the fixed frequency oscillation circuit 102 and the variable frequency electrical signal generated by the variable frequency oscillation circuit 103. The audio electrical signal is formed from a wave whose voltage changes with time, and represents audio. The wave has a variable frequency, and the frequency indicates a difference obtained by subtracting the frequency of the wave indicated by the variable frequency electric signal from the frequency of the wave indicated by the fixed frequency electric signal, and is in a range of 100 Hz to 3200 kHz. One frequency is shown.

  The audio amplifying device 107 generates an amplified audio electric signal by amplifying the audio electric signal generated by the frequency difference circuit 105. The amplified audio electrical signal is formed from a wave whose voltage changes periodically with time. The speaker 108 generates the sound indicated by the audio electrical signal based on the amplified audio electrical signal generated by the audio amplification device 107.

  The operation of the electronic musical instrument 100 includes a zero point adjustment and a performance operation.

  The zero point adjustment is executed before playing the music using the electronic musical instrument 100. The user first sets the frequency of the wave formed by the variable frequency electrical signal to 499.9 kHz when the hand 112 is sufficiently away from the antenna 111, and the hand 112 is sufficiently close to the antenna 111. The variable frequency oscillation circuit 103 is adjusted so that the frequency of the wave formed by the variable frequency electrical signal is 496.8 kHz.

  The performance operation is executed after the zero point adjustment is executed. The user puts the hand 112 on the antenna 111 and brings the hand 112 closer to the antenna 111 or moves the hand 112 away from the antenna 111. At this time, the stray capacitance between the performer's hand 112 and the antenna 111 is changed by bringing the hand 112 close to the antenna 111 or moving the hand 112 away from the antenna 111, that is, the hand 112 and the antenna. It decreases monotonically with the distance to 111.

  The variable frequency oscillation circuit 103 of the electronic musical instrument 100 generates a variable frequency electric signal indicating a wave having a frequency corresponding to the stray capacitance within the range of 496.8 kHz to 499.9 kHz. The fixed frequency oscillation circuit 102 generates a fixed frequency electric signal indicating a wave whose frequency is constant at 500 kHz. The frequency difference circuit 105 generates an audio electric signal indicating a wave having a frequency obtained by subtracting the frequency of the wave indicated by the variable frequency electric signal from the frequency of the wave indicated by the fixed frequency electric signal. That is, the frequency indicates one frequency in the range of 100 Hz to 3200 kHz.

  The audio amplifying device 107 amplifies the audio electric signal to generate an amplified audio electric signal indicating the audio. The speaker 108 generates the sound by converting the amplified sound electric signal into the sound.

  According to such an operation, the user can cause the electronic musical instrument 100 to generate a musical tone having a desired pitch by placing the hand 112 at a predetermined distance from the antenna 111. For this reason, the user can play a desired musical piece using the electronic musical instrument 100 by bringing the hand 112 closer to the antenna 111 or moving the hand 112 away from the antenna 111.

  If the frequency of the sound generated by the electronic musical instrument 100 is 100 Hz when the oscillation frequency of the fixed frequency oscillation circuit 102 is about 500 kHz, the sound frequency corresponds to 0.02% (100/500000) of the oscillation frequency. . For this reason, the electronic musical instrument 100 may not be able to generate the sound from the electronic musical instrument 100 if the oscillation frequency of the fixed frequency oscillation circuit 102 or the variable frequency oscillation circuit 103 varies by about 0.02%. These oscillators are difficult to tune in the initial stage unless the elements that determine the frequency (in many cases, the inductance of the coil, the capacitance of the capacitor, and other parts of the power supply and oscillation circuit) are not stable. Stable performance becomes difficult. An electronic musical instrument that can be played more easily is desired, and an electronic musical instrument that is manufactured at a lower cost is desired.

Theremin operating principle, [online], [April 8, 2011 search], Internet <URL: http: // www. asahi-net. or. jp / ˜uu9m-hrt / thereminn / thereminn2. htm>

An object of the present invention is to provide an electronic musical instrument that can be played more easily.
Another object of the present invention is to provide an electronic musical instrument that is manufactured at a lower cost.

  In the following, means for solving the problems will be described using the reference numerals used in the modes and examples for carrying out the invention in parentheses. This symbol is added to clarify the correspondence between the description of the claims and the description of the modes and embodiments for carrying out the invention. Do not use to interpret the technical scope.

  An electronic musical instrument (1) according to the present invention includes a fixed frequency oscillation circuit (2), a variable frequency oscillation circuit (3), a frequency difference circuit (5), an audio generation circuit (6) (21), and an audio device (7, 8). And. The fixed frequency oscillation circuit (2) generates a fixed frequency electric signal indicating a fixed frequency wave having a fixed frequency. The variable frequency oscillation circuit (3) generates a variable frequency electric signal indicating a variable frequency wave whose frequency changes based on the stray capacitance between the moving body (12) and the antenna (11). The frequency difference circuit (5) generates a difference electric signal indicating a difference frequency wave having a frequency difference between the frequency of the fixed frequency wave and the frequency of the variable frequency wave. The voice generation circuits (6) and (21) convert the voice electric signal indicating the voice waveform based on the difference electric signal so that the frequency of the fundamental wave of the voice waveform is smaller than the frequency of the fundamental wave of the difference frequency wave. Generate. The audio device (7, 8) generates the audio indicated by the audio waveform based on the audio electrical signal.

  The fixed frequency oscillation circuit (2) is formed of a CR oscillation circuit. The variable frequency oscillation circuit (3) is formed from another CR oscillation circuit different from the CR oscillation circuit.

  The sound generation circuit (21) generates an electric signal formed from a current corresponding to the frequency of the fundamental wave of the difference frequency wave, and converts the sound electric signal based on the electric signal. And an audio generation circuit (24, 25) for generation.

  The sound generation circuits (6) and (21) are based on the frequency reduction circuits (14) (22, 23, and 24) that generate the divided electric signal by dividing the difference electric signal, and the divided electric signal. And an audio adjustment circuit (15) (25) for generating the audio electric signal.

  In the electronic musical instrument according to the present invention, the influence of the fluctuation of the frequency of the fixed frequency wave and the frequency of the variable frequency wave on the pitch of the sound is small, and adjustment of the fixed frequency oscillation circuit and the variable frequency oscillation circuit is unnecessary. Yes, the performance by the user can be made easier.

FIG. 1 is a block diagram showing a known electronic musical instrument. FIG. 2 is a block diagram showing an electronic musical instrument according to the present invention. FIG. 3 is a block diagram showing another sound generation circuit.

  An embodiment of an electronic musical instrument according to the present invention will be described with reference to the drawings. As shown in FIG. 2, the electronic musical instrument 1 includes a fixed frequency oscillation circuit 2, a variable frequency oscillation circuit 3, a frequency difference circuit 5, a sound generation circuit 6, a sound amplification device 7, and a speaker 8. . The fixed frequency oscillation circuit 2 generates a fixed frequency electric signal when the electronic musical instrument 1 is activated. The fixed frequency electrical signal is formed from a wave whose voltage changes periodically with time. The wave has a constant frequency and is fixed at a fixed frequency. An example of the fixed frequency is 500 kHz.

  The variable frequency oscillation circuit 3 includes an antenna 11. The variable frequency oscillation circuit 3 generates a variable frequency electric signal when the electronic musical instrument 1 is activated. The variable frequency electrical signal is formed from a wave whose voltage changes periodically with time. The frequency of the wave is variable, and the frequency changes based on the stray capacitance between the player's hand 12 and the antenna 11. The frequency monotonously decreases with respect to the distance between the hand 12 and the antenna 11, and shows one frequency in the range of 397.6 kHz to 487.2 kHz. That is, the variable frequency oscillation circuit 3 is such that when the hand 12 is sufficiently away from the antenna 11, the frequency shows the maximum value in the range, and the hand 12 is sufficiently close to the antenna 11. Sometimes it is made so that its frequency shows the minimum of its range.

  The frequency difference circuit 5 generates a differential frequency electrical signal based on the fixed frequency electrical signal generated by the fixed frequency oscillation circuit 2 and the variable frequency electrical signal generated by the variable frequency oscillation circuit 3. The differential frequency electrical signal is formed from a wave whose voltage changes periodically with time. The wave has a variable frequency, and the frequency indicates a difference obtained by subtracting the frequency of the wave indicated by the variable frequency electric signal from the frequency of the wave indicated by the fixed frequency electric signal, that is, 3.2 kHz to 102 kHz. Shown is one frequency in the range of 4 kHz.

  The sound generation circuit 6 generates a sound electric signal based on the difference frequency electric signal generated by the frequency difference circuit 5. That is, the sound generation circuit 6 includes a frequency divider 14 and a sound adjustment circuit 15. The frequency divider 14 divides the differential frequency electrical signal by 32 to generate a frequency-divided electrical signal. That is, the frequency-divided electric signal is formed from a pseudo sine wave whose voltage periodically changes with time. The pseudo sine wave has a variable frequency, and the frequency indicates a quotient obtained by dividing the frequency of the wave indicated by the differential frequency electric signal by 32, that is, one frequency in a range of 100 Hz to 3200 Hz. ing. The audio adjustment circuit 15 generates the audio electric signal by shaping the waveform of the frequency-divided electric signal generated by the frequency divider 14. The audio electric signal is an audio signal formed from a wave whose voltage changes periodically with time and formed from another waveform different from the pseudo sine wave. The pitch of the sound is variable and is equal to the frequency of the pseudo sine wave indicated by the frequency-divided electric signal.

  The audio amplifying device 7 generates an amplified audio electric signal by amplifying the audio electric signal generated by the audio adjusting circuit 15. The amplified audio electrical signal is formed from a wave whose voltage periodically changes with time, and indicates the audio represented by the audio electrical signal. The speaker 8 converts the amplified audio electrical signal generated by the audio amplifying device 7 into the audio.

  When a user plays a musical piece using the electronic musical instrument 1, after the electronic musical instrument 1 is activated, the user places the hand 12 on the antenna 11, brings the hand 12 close to the antenna 11, or moves the hand 12 away from the antenna 11. Or At this time, the stray capacitance between the performer's hand 12 and the antenna 11 is changed by bringing the hand 12 closer to the antenna 11 or moving the hand 12 away from the antenna 11, that is, the hand 12 and the antenna 11. 11 decreases monotonously with the distance.

  The variable frequency oscillation circuit 3 of the electronic musical instrument 1 generates a variable frequency electric signal indicating a wave having a frequency corresponding to the stray capacitance within the range of 397.6 kHz to 487.2 kHz. The fixed frequency oscillation circuit 2 generates a fixed frequency electric signal indicating a wave whose frequency is constant at 500 kHz. The frequency difference circuit 5 generates a differential frequency electric signal indicating a wave having a frequency obtained by subtracting the frequency of the wave indicated by the variable frequency electric signal from the frequency of the wave indicated by the fixed frequency electric signal. That is, the frequency indicates one frequency in the range of 3.2 kHz to 102.4 kHz.

  The frequency divider 14 divides the differential frequency electric signal by 32 to generate a frequency divided electric signal indicating a pseudo sine wave. That is, the frequency of the pseudo sine wave coincides with the quotient obtained by dividing the frequency of the wave indicated by the differential frequency electric signal by 32, that is, one frequency in the range of 100 Hz to 3200 Hz.

  The sound adjustment circuit 15 shapes the frequency-divided electric signal to generate a sound electric signal indicating sound formed from another waveform different from the pseudo sine wave. The pitch of the sound is variable and is equal to the frequency of the pseudo sine wave indicated by the frequency-divided electric signal, that is, one frequency in the range of 100 Hz to 3200 Hz.

  The audio amplifying device 7 amplifies the audio electric signal to generate an amplified audio electric signal indicating the audio. The speaker 8 generates the sound by converting the amplified sound electric signal into the sound.

  According to such an operation, the user can cause the electronic musical instrument 1 to generate a musical tone having a desired pitch by placing the hand 12 at a predetermined distance from the antenna 11. For this reason, the user can play a desired musical piece using the electronic musical instrument 1 by bringing the hand 12 close to the antenna 11 or moving the hand 12 away from the antenna 11.

  Furthermore, in the electronic musical instrument 1, the fluctuation of the oscillation frequency of the fixed frequency oscillation circuit 2 or the variable frequency oscillation circuit 3 is generated by the electronic musical instrument 1 as compared with the known electronic musical instrument 100 shown in FIG. The effect on the pitch is smaller. For example, the electronic musical instrument 100 shown in FIG. 1 generates a musical tone having a desired pitch from the electronic musical instrument 100 when the oscillation frequency of the fixed frequency oscillation circuit 102 or the variable frequency oscillation circuit 103 varies by about 0.02%. May not be possible. On the other hand, the electronic musical instrument 1 can generate a musical tone having a desired pitch from the electronic musical instrument 1 even if the oscillation frequency of the fixed frequency oscillation circuit 2 or the variable frequency oscillation circuit 3 varies by about 0.02%.

  For this reason, the electronic musical instrument 1 does not require the zero point adjustment necessary for the electronic musical instrument 100 described above, and the user can play the electronic musical instrument 1 more easily. The electronic musical instrument 1 can further employ a low-stability oscillator different from the crystal oscillator for the fixed frequency oscillation circuit 2 and the variable frequency oscillation circuit 3. Examples of the oscillator include an LC oscillator and a CR oscillation circuit. The electronic musical instrument 1 can be manufactured at a lower cost when the oscillator is employed as the fixed frequency oscillation circuit 2 and the variable frequency oscillation circuit 3.

  In the electronic musical instrument according to the present invention, the sound generation circuit 6 in the above-described embodiment can be replaced with another sound generation circuit. As shown in FIG. 3, the sound generation circuit 21 includes an FV conversion circuit 22, a VI conversion circuit 23, an I-F conversion circuit 24, and a sound generation circuit 25.

  The FV conversion circuit 22 generates a first electric signal formed from a wave whose voltage changes with time by FV converting the differential frequency electric signal. The voltage corresponds to the frequency of the wave indicated by the differential frequency electrical signal and increases monotonously with respect to the frequency of the wave indicated by the differential frequency electrical signal.

  The V-I conversion circuit 23 performs a V-I conversion on the first electric signal, thereby generating a second electric signal formed from a wave whose current changes with time. The current corresponds to the voltage indicated by the first electrical signal and increases monotonically with respect to the voltage indicated by the first electrical signal.

  The IF conversion circuit 24 performs IF conversion on the second electric signal, thereby generating a third electric signal formed from a wave whose frequency changes with time. The frequency corresponds to the current indicated by the second electrical signal and increases monotonically with respect to the current indicated by the second electrical signal. An example of the IF conversion circuit 24 is a ring oscillator.

  The sound generation circuit 25 generates a sound electric signal formed from a wave whose voltage periodically changes with time by a digital waveform generator using the third electric signal as a clock signal. The pitch of the sound is variable and is lower than the wave frequency indicated by the third electric signal. Examples of the sound include musical sounds generated by musical instruments, animal calls, words, and sound effects. Examples of the musical instrument include an organ and a violin. Examples of such animals include cats and frogs.

  The electronic musical instrument to which the sound generation circuit 21 is applied can make playing easier in the same manner as the electronic musical instrument 1 in the above-described embodiment.

  A sound generation IC in which an IF conversion circuit 24 and a sound generation circuit 25 are integrated is known. Such sound generation ICs are mass-produced and marketed at a relatively low cost. Such an audio generation IC can be applied to an electronic musical instrument to which the audio generation circuit 21 is applied, and can be manufactured at a relatively low cost.

  In the electronic musical instrument 1, the frequency divider 14 can be replaced with another frequency reduction circuit. The frequency reduction circuit generates a frequency-divided electric signal indicating a wave having a frequency equal to a quotient obtained by dividing the frequency of the wave indicated by the differential frequency electric signal by 32. Examples of the frequency reduction circuit include a set of an FV conversion circuit 22, a VI conversion circuit 23, and an IF conversion circuit 24. An electronic musical instrument to which such a frequency reduction circuit is applied can make playing easier in the same manner as the electronic musical instrument 1 in the above-described embodiment.

1: Electronic musical instrument 2: Fixed frequency oscillation circuit 3: Variable frequency oscillation circuit 5: Frequency difference circuit 6: Audio generation circuit 7: Audio amplification device 8: Speaker 11: Antenna 12: Hand 14: Divider 15: Audio adjustment circuit 21: Audio generation circuit 22: F-V conversion circuit 23: V-I conversion circuit 24: I-F conversion circuit 25: Audio generation circuit

Claims (4)

A fixed frequency oscillation circuit that generates a fixed frequency electric signal indicating a fixed frequency wave having a fixed frequency; and
A variable frequency oscillating circuit for generating a variable frequency electric signal indicating a variable frequency wave whose frequency changes based on a stray capacitance between the moving body and the antenna;
A frequency difference circuit that generates a difference electric signal indicating a difference frequency wave having a frequency difference between the frequency of the fixed frequency wave and the frequency of the variable frequency wave;
A sound generation circuit that generates a sound electrical signal indicating a sound waveform based on the differential electrical signal;
An audio device that generates the audio indicated by the audio waveform based on the audio electrical signal;
An electronic musical instrument in which a frequency of a fundamental wave of the speech waveform is smaller than a frequency of a fundamental wave of the difference frequency wave. In claim 1,
The fixed frequency oscillation circuit is formed of a CR oscillation circuit,
The variable frequency oscillation circuit is an electronic musical instrument formed from another CR oscillation circuit different from the CR oscillation circuit. In any one of Claims 1-2.
The sound generation circuit includes:
A conversion circuit that generates an electric signal formed from a current corresponding to the frequency of the fundamental wave of the differential frequency wave;
An electronic musical instrument comprising: a sound generation circuit that generates the sound electric signal based on the electric signal. In any one of Claims 1-2.
The sound generation circuit includes:
A frequency reduction circuit that generates a divided electric signal by dividing the differential electric signal;
An electronic musical instrument comprising: an audio adjustment circuit that generates the audio electric signal based on the divided electric signal.

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