JP2669439B2 - Waveform editing method - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a waveform editing method capable of creating an acoustic waveform signal whose tone or pitch has been changed based on a stored acoustic waveform signal. Background of the Invention Conventionally, an acoustic waveform signal read from a storage device and an acoustic waveform signal input from a microphone are combined, and the combined acoustic waveform signal is stored again in the storage device, There is one that obtains various acoustic waveform signals (Japanese Patent Laid-Open No. 55-166698).
issue). However, the conventional one simply mixes two waveforms (A waveform and B waveform) to obtain a completely new waveform (A + B waveform), and a specific waveform (A waveform stored in the waveform memory from the beginning). It was impossible to obtain waveforms with different characteristics, such as timbre or pitch. Further, in the conventional device, the synthesized waveform signal is written in the storage area of the specific waveform (A waveform) that is stored from the beginning, so the specific waveform disappears,
Once the acoustic waveform signal is generated, there is a problem that it is impossible to use the original acoustic waveform signal. [Object of the Invention] The present invention has been made in view of the above problems of the related art, and various acoustic waveform signals different in tone color and pitch from the acoustic waveform signal stored in advance are left as they are. An object of the present invention is to provide a waveform editing method capable of creating and storing. SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a tone color characteristic of an acoustic sound generated by the acoustic waveform signal read from a storage unit that stores the acoustic waveform signal in a predetermined area among a plurality of areas. Input processing for inputting the degree of change of the tone color characteristic, and change processing for changing the tone color characteristic of the acoustic sound generated by the acoustic waveform signal read from the storage means based on the degree of change of the tone color characteristic input in this input processing And a re-input process of re-inputting the acoustic waveform signal whose tone color characteristic has been changed by this changing process into another area different from the predetermined area of the storage means. The present invention also provides an input process for inputting a reading speed for reading out the acoustic waveform signal from storage means for storing an acoustic waveform signal sampled at a predetermined sampling frequency in a predetermined area among a plurality of areas; A reading process of reading the acoustic waveform signal from the storage unit based on the reading speed input in the process; and reading the acoustic waveform signal read in the reading process with the predetermined area of the storage unit. The key point is that it consists of re-input processing to re-input to a different area. [Example] Hereinafter, the present invention will be described in detail with reference to an example shown in the drawings. FIG. 1 shows a circuit configuration of the present embodiment. An input signal (IN) is appropriately amplified by an input amplifier 1 and then supplied to an analog adder circuit 2, and a filter 3 removes high frequency components. After that, the sample and hold circuit (S /
H) 5 is sampled at an appropriate sampling frequency and supplied to the A / D converter 6. The A / D converter 6 converts an input analog signal into a corresponding digital signal,
It is supplied to the sound control unit 8. The tone generation control unit 8 has, for example, four waveform reading / writing channels, and can independently write or read a waveform signal to or from the waveform memory 7. The specific configuration of the tone control unit 9 is described in Japanese Patent Application No. 59-167119, and a detailed description thereof will be omitted. The sound generation control unit 8 operates under the control of the CPU 9 including a microcomputer,
Digital signals corresponding to a maximum of four tones are read from the waveform memory 7 in a time-divisional manner corresponding to the four waveform reading / writing channels of the sound generation control unit 8 and are time-divided to the D / A converter 10. To the sample and hold circuits (S / H) 11a to 11d. The sample and hold circuit 11a~11d is the timing signal t ₁ ~t ₄ described later, each time-division processing channel time, performs the sampling operation. The voltage signals held by the sample and hold circuits 11a to 11d are VCF (voltage controlled filters) 12a to
12d, correspondingly supplied. Voltage signals FCV1 to FCV4, which will be described later, are supplied to the respective VCFs 12a to 12d, and filtering processing is independently performed according to the voltage signals FCV1 to FCV4. Then, the VCFs 12a to 12d send the filtered analog waveform signals to the VCAs (voltage controlled amplifiers) 13a to 13d. The VCAs 13a to 13d are supplied with control voltage signals ACV1 to ACV.
The amplification rate is controlled independently by CV4, VCF12a ~ 12d
The output level or the volume envelope for the supplied waveform signal is determined. Then, the output signals of the VCAs 13a to 13d are sent to the outside as outputs OUT1 to OUT4 of the respective channels, and are appropriately amplified and then emitted as acoustic signals. Further, the outputs of the VCAs 13a to 13d can be supplied to the analog adder circuit 14, mixed, and taken out as a mix output OUTMIX to the outside. Further, the output of the VCF 12d corresponding to the above-mentioned fourth channel and the output of the analog adding circuit 14 are analog switches that perform switching operation according to the control signal from the CPU 9 described above.
Supplied to 15. The analog switch 15 selects the output of the VCF 12d and the output of the analog adder circuit 14 and supplies it to the VCA (voltage control type amplifier) 16. The VCA 16 amplifies the voltage in accordance with the supplied control voltage signal ACV0, and feeds it back to the analog addition circuit 2 described above. Therefore, the external sound signal supplied via the input amplifier 1 and the waveform signal obtained by reading the waveform memory 7 can be mixed by the amplifier adding circuit 2 and supplied again to the waveform memory 7. Reference numeral 4 in the figure denotes a keyboard / display unit including a keyboard having performance keys and various control switches, and a liquid crystal display panel for displaying various states. The CPU 9 and the keyboard / display unit 4 exchange data with each other. I do. The CPU 9 converts the digital signal into a D / A converter to generate the control signals FCV1 to FCV4, ACV1 to ACV4, and ACV0 (hereinafter collectively referred to as a control signal CV) by software processing. It is supplied to the group 17 and converted into respective voltage signals. This D / A converter group 17 may have a number of D / A converters corresponding to the number of control signals CV, or use one D / A converter in a time-division manner, A required number of control signals CV may be obtained in combination with the sample and hold circuit. Next, the operation of this embodiment will be described. FIG. 2 is a time-division processing state of a plurality of channels of the tone generation control unit 8 and timing signals supplied to the sample and hold circuits 11a to 11d.
shows the relationship between t ₁ ~t _4, as described above, in the present embodiment is realized by time-division configure four waveform readout and writing channels, for each waveform reading and writing channels, It is possible to selectively specify whether to perform read processing or write processing. In the state shown in FIG. 2, the waveform memory 7 is stored in the waveform memory 7 by the processing of channel 1 (ch1). The waveform signal obtained via the filter 3, the sample and hold circuit 5, and the A / D converter 6 is written, and the other channels 2 to 4 (ch2 to
In 4), the digital waveform signal in a predetermined area can be read from the waveform memory 7. Further, the timing signals t _{1 to} t ₄ described above are set to the high level at the time corresponding to each channel (ch1 to 4), and the D / A converter 10 is operated at each channel time.
The analog / waveform signal output from the sample / hold circuits 11a to 11d is sampled and then held. FIG. 3 shows a state of area division of the waveform memory 7, for example, N pieces of waveform information can be recorded in a variable length. Each of the waveform read / write channels of the tone generation control section 8 can independently specify an area to be read / written, and, for example, channels 2, 3, 4 can be designated.
Then, read out the tones 1, 2, and 3 in FIG.
~ 12d, VCA13b ~ 13d process control, analog adder circuit
14. After being supplied to the analog adder 2 via the switch 15, the VCA 16 and mixed with an external sound signal as required,
It is input via the sample and hold circuit 5 and A / D converter 6, and the tone N is processed by the processing of channel 1.
It is recorded in the waveform memory 7 again. That is, an overdubbing process can be performed. In addition, the CPU 9 sends a switching signal to the analog switch 15, and the waveform memory 7 is processed by the channel 4.
Sample and hold circuit 11
d, and further applied to the VCA 16 via the VCF 12d. The waveform signal obtained in this manner is supplied to the analog adder 2 and mixed with an external sound signal in the same manner as described above. It is also possible to write in a predetermined area of the memory 7. Next, with reference to the flowchart of FIG. 4, the processing mainly in the CPU 9 in the overdubbing mode will be described in detail. CPU9 by the switch operation of the keyboard / display unit 4
But when it is specified to overdub mode, first, the waveform signal that has already been stored in the waveform memory 7, to determine the reading carded in association with any scale frequency, in step S _1, the keyboard and display unit Judge whether the keyboard operation of 4 was performed. That is, in the present embodiment, the frequency of the musical tone to be generated by the key operation on the keyboard is specified.
The waveform signal recorded in the waveform memory 7 will be output from the waveform memory 7 at a high read rate if the treble range is designated, and will be output at a low read rate if the bass range is designated. , From the waveform memory 7. Then, if there is a key input in this step S ₁ , it is determined Yes, and the process proceeds to step S ₂ . In step S ₂ , the waveform memory 7 specified on the keyboard / display unit 4 at that time is displayed.
The CPU 9 stores the number of the tone to be read from the key together with the scale specified by the key operation. Further, the CPU 9 stores the information for determining the corresponding volume. Then, then the process proceeds to Step S _3. Even when the determination of No is made in step S ₁ , the process proceeds to step S ₃ . Step S ₃ is a step of actually trigger signal for starting the recording is judge whether supplied from the keyboard and display unit 4, if still returns to S ₁ again to be applied, following steps S ₁ → S ₃ Alternatively, steps S ₁ → S ₂ → S ₃ are repeated to enter the standby state. Therefore, when a plurality of keys are operated on the keyboard, it is possible to assign a maximum of three scales to channels 2, 3 and 4, and if different tone numbers are respectively designated, waveforms of different tones are formed. The signal is at the specified scale,
If the same tone number is specified for each channel, the waveform signal of the same tone color is
It will be played and overdubbed with a different volume. In step S _3, if there is a trigger input, Ye
The determination of s is made, and the process proceeds to step S ₄ . In step S ₃ , a trigger input may be automatically given to the CPU 9 when the input signal (IN) exceeds a predetermined level, and the process may proceed to step S ₄ . In step S _4, the tone number CPU9 is saved, the scale information, and supplies to the tone generation control unit 8, for each waveform reading and writing channels, identifies the area of reading waveform data from the waveform memory 7, and its Specify the scale. Next, proceeding to step S ₅ , the CPU 9 sends a digital signal for generating each control signal to the D / A converter group 17, generates a voltage control signal CV, and outputs each VCF 12a to 12d, VCA.
The control signals CV are sent to the 13a to 13d and VCA16, respectively. Further, the CPU 9 supplies a switching signal to the analog switch 15 so as to supply the mixed waveform signal from the adder circuit 14 to the VCA 16. Then, proceeding to step S ₆ , the CPU 9 starts actual recording using channel 1. At this time, the designated one of the channels 2 to 4 operates so as to generate the acoustic signal that has already been determined by reading the waveform data from the waveform memory 7. Then, when the input process is completed, the end state is set,
The CPU 9 comes back to the processing of the main routine (not shown). As described above, in the present embodiment, the sound generation control unit 8 has four
The waveform signal can be read and written independently on one of the waveform read / write channels, and the same or separate digital signal can be read from the waveform memory on at least two channels. , VCA
After independently controlling the tone and volume in 13a to 13d, mixing and writing to the waveform memory 7 using a specific channel as a new sound source signal, the overdubbing function should be enhanced. It is possible, and it is also musically preferable. Also, waveform data is read from the waveform memory 7 using up to three of the four waveform read / write channels, and if necessary, the reproduced waveform data is combined with the input waveform signal (IN) to generate a sound source. Since it can be waveform data, various modes of overdubbing can be adopted. Also, the waveform memory 7 is divided into a plurality of areas for use,
The waveform signal obtained as a result of overdubbing can be written in an area different from the area in which the original waveform signal is recorded, and it is possible to perform overdubbing without erasing the original waveform signal. Also, VC signals are applied to each of the waveform signals read out from the waveform memory 7 by the plurality of waveform read / write channels.
The volume level can be set independently using A13a to 13d. Also, the same waveform data can be read from the same memory area at different scale frequencies using a plurality of waveform read / write channels, and can be synthesized while varying the synthesis ratio with the VCAs 13a to 13d. In the embodiment described above, the tone technology and the sound volume are variably controlled by analog technology, that is, VCFs 12a to 12d and VCA 13a to 13d. Variable control such as timbre, volume or envelope may be performed, in which case all the processing can be performed by digital signal processing. Further, other processing may be performed on the waveform signal. As the circuit configuration of the tone generation control unit 8, in addition to the configuration in which a plurality of waveform reading / writing channels are formed by time division processing as in the above-described embodiment, separate hardware, that is, the same circuit configuration as the number of channels is used. One may be used to provide multiple waveform read / write channels. Further, among the plurality of channels, a specific channel may be a write-only channel for writing a waveform signal to the waveform memory 7, and the other channels may be read-only channels for reading a waveform signal from the waveform memory 7. .
The “waveform read / write channel” in the present invention means either one of read and write, or a channel that enables both operations. EFFECTS OF THE INVENTION According to the present invention, an acoustic waveform signal having a different tone color characteristic and pitch is created separately from the acoustic waveform signal stored from the beginning, based on the input tone color characteristic and the degree of change in pitch. Can be stored. Thus, for example, when used for generating a sound source waveform of a musical sound generating device or the like, a wide variety of sound source signals can be easily obtained, and an effect that various musical sounds can be generated is exerted.

BRIEF DESCRIPTION OF THE DRAWINGS The drawings show one embodiment of the present invention, FIG. 1 is a circuit configuration diagram thereof, FIG. 2 is a time chart for explaining the operation thereof, and FIG. 3 is a waveform memory. FIG. 4 is a view showing a storage state, and FIG. 4 is a view showing a flow chart for explaining the operation of the same embodiment. 2 ... Analog adder circuit, 4 ... Keyboard / display,
6 ... A / D converter, 7 ... waveform memory, 8 ... sound control unit, 9 ... CPU, 10 ... D / A converter, 12a-12d ... VCF, 1
3a to 13d ... VCA, 14 ... Analog adder, 17 ... D / A converter group.

   ────────────────────────────────────────────────── ─── Continuation of front page        Panel     Judge Okumura Juichi     Judge Ryoji Iio     Referee Tadayuki Watanabe                (56) Reference JP-A-55-161293 (JP, A)                 JP-A-51-94909 (JP, A)                 JP 55-166698 (JP, A)                 JP-A-60-52895 (JP, A)                 JP-A-54-161313 (JP, A)

Claims (1)

(57) [Claims] An input process for inputting a degree of change in timbre characteristics of an acoustic sound generated by the acoustic waveform signal read out from storage means for storing an acoustic waveform signal in a predetermined area of a plurality of areas; Change processing for changing the tone color characteristic of the acoustic sound generated by the acoustic waveform signal read from the storage means based on the changed degree of the tone color characteristic, and the acoustic waveform signal with the tone color characteristic changed by this change processing. And a re-inputting process for re-inputting into a different area of the storage means different from the predetermined area. 2. An input process for inputting a reading speed for reading out the acoustic waveform signal from storage means for storing the acoustic waveform signal sampled at a predetermined sampling frequency in a predetermined area among a plurality of areas; A reading process of reading the acoustic waveform signal from the storage means based on the read speed, and placing the acoustic waveform signal read in the reading process in another area different from the predetermined area of the storage means. A re-input process for re-inputting, and a waveform editing method comprising: