초록 ▼

An electronic hi-hat cymbal comprises a hi-hat having a strike detector, a pedal unit having a stepped degree detector, a waveform data memory for storing a plurality of electronic hi-hat sound waveform data, corresponding to respective stepped degrees, in a plurality of stages, a CPU, a musical ton

An electronic hi-hat cymbal comprises a hi-hat having a strike detector, a pedal unit having a stepped degree detector, a waveform data memory for storing a plurality of electronic hi-hat sound waveform data, corresponding to respective stepped degrees, in a plurality of stages, a CPU, a musical tone generating controller, and so forth. The CPU causes the musical tone generating controller to read out electronic hi-hat sound waveform data corresponding to a stepped degree in the pedal unit from the waveform data memory when a strike to the hi-hat is detected to thereby generate a musical tone signal before outputting, and when a change occurs to the stepped degree during a musical tone being produced thereafter, to read out electronic hi-hat sound waveform data corresponding to a new stepped degree halfway through to thereby generate a musical tone signal to be outputted, which is continued while the musical tone is being produced.

대표청구항 ▼

What is claimed is: 1. An electronic hi-hat cymbal comprising a hi-hat having a strike detector for detecting a strike, a pedal unit having a stepped degree detector for detecting a stepped degree of a pedal, a waveform data memory for storing a plurality of electronic hi-hat sound waveform data, c

What is claimed is: 1. An electronic hi-hat cymbal comprising a hi-hat having a strike detector for detecting a strike, a pedal unit having a stepped degree detector for detecting a stepped degree of a pedal, a waveform data memory for storing a plurality of electronic hi-hat sound waveform data, corresponding to the respective stepped degrees, in a plurality of stages, detectable by the stepped degree detector, and a musical tone generator; wherein the musical tone generator reads out electronic hi-hat sound waveform data corresponding to a stepped degree detected by the stepped degree detector from the waveform data memory when a strike is detected by the strike detector to thereby generate a musical tone signal before outputting, and in the case where a change occurs to the stepped degree detected by the stepped degree detector during a musical tone being produced thereafter, the musical tone generator reads out electronic hi-hat sound waveform data corresponding to a new stepped degree halfway through to thereby generate a musical tone signal before outputting. 2. An electronic hi-hat cymbal according to claim 1, wherein the sound waveform of the electronic hi-hat is a sound waveform with an amplitude envelope value decreasing in time sequence; and wherein the musical tone generator reads out the electronic hi-hat sound waveform data from the start thereof when the electronic hi-hat sound waveform data are read out for the first time from the waveform data memory upon the detection of the strike, and the musical tone generator reads out electronic hi-hat sound waveform data corresponding to a new stepped degree from an address of an amplitude envelope value corresponding to an amplitude envelope value of a sound waveform of the electronic hi-hat, being read at that point in time, when a change occurs to the stepped degree during a musical tone being produced thereafter. 3. An electronic hi-hat cymbal according to claim 1, wherein the sound waveform of the electronic hi-hat is a sound waveform with an amplitude envelope value decreasing in time sequence; and wherein the musical tone generator reads out the electronic hi-hat sound waveform data from the start thereof when the electronic hi-hat sound waveform data are read out for the first time from the waveform data memory upon the detection of the strike, and the musical tone generator reads out electronic hi-hat sound waveform data corresponding to a new stepped degree from an address at the same position from the start in time sequence, being read at that point in time, when a change occurs to the stepped degree during a musical tone being produced thereafter. 4. An electronic hi-hat cymbal according to claim 1, wherein the musical tone generator causes the musical tone signal to fade out, and causes a musical tone signal according to newly read electronic hi-hat sound waveform data to fade in, thereby mixing it therewith before outputting, when a change occurs to the stepped degree during a musical tone signal being outputted. 5. An electronic hi-hat cymbal according to claim 2, wherein the musical tone generator causes the musical tone signal to fade out, and causes a musical tone signal according to newly read electronic hi-hat sound waveform data to fade in, thereby mixing it therewith before outputting, when a change occurs to the stepped degree during a musical tone signal being outputted. 6. An electronic hi-hat cymbal according to claim 3, wherein the musical tone generator causes the musical tone signal to fade out, and causes a musical tone signal according to newly read electronic hi-hat sound waveform data to fade in, thereby mixing it therewith before outputting, when a change occurs to the stepped degree during a musical tone signal being outputted. 7. An electronic hi-hat cymbal according to claim 1, wherein the musical tone generator reads out two sound waveform data corresponding to respective stepped degrees of the two adjacent stages, and mixes respective musical tone signals according to the two sound waveform data at a mixing ratio corresponding to the stepped degree detected before being outputted, if the stepped degree detected by the stepped degree detector falls between two adjacent stages among the plurality of stages. 8. An electronic hi-hat cymbal according to claim 2, wherein the musical tone generator reads out two sound waveform data corresponding to respective stepped degrees of the two adjacent stages, and mixes respective musical tone signals according to the two sound waveform data at a mixing ratio corresponding to the stepped degree detected before being outputted, if the stepped degree detected by the stepped degree detector falls between two adjacent stages among the plurality of stages. 9. An electronic hi-hat cymbal according to claim 3, wherein the musical tone generator reads out two sound waveform data corresponding to respective stepped degrees of the two adjacent stages, and mixes respective musical tone signals according to the two sound waveform data at a mixing ratio corresponding to the stepped degree detected before being outputted,. if the stepped degree detected by the stepped degree detector falls between two adjacent stages among the plurality of stages. 10. An electronic hi-hat cymbal according to claim 1, wherein the strike detector is capable of detecting a strike strength as well, and the musical tone generator generates a musical tone signal by increasing or decreasing amplitude value of the sound waveform of the electronic hi-hat as read out, according to the strike strength detected by the strike detector. 11. An electronic hi-hat cymbal according to claim 1, wherein the stepped degree of a pedal, detected by the stepped degree detector, is caused to correspond to an opening degree between two cymbals of a hi-hat cymbal of an acoustic percussion instrument, and the plurality of the electronic hi-hat sound waveform data stored in the waveform data memory is caused to be electronic hi-hat sound waveform data equivalent to hi-hat strike sounds corresponding to the respective opening degrees between the two cymbals.