JP4205229B2 - Effect imparting device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an effect imparting device that imparts an effect to an input musical sound signal, and more particularly to generation of an envelope waveform used for imparting an effect.
[0002]
[Prior art]
Conventionally, some effect imparting devices use an envelope signal to impart an effect. For example, in the synthesizer, the attack time, decay time, and release time of the envelope waveform are set for each musical sound, and the envelope of the musical sound that is sounded is depressed every time the key is pressed. There was something to do.
[0003]
[Problems to be solved by the invention]
However, in such a configuration, every time a musical sound is generated, it is only possible to give an effect to the musical sound, and the music represented by the musical sound signal with respect to the musical sound signal continuously supplied from the outside. An effect that matches the tempo cannot be given.
[0004]
SUMMARY OF THE INVENTION An object of the present invention is to provide an effect applying device that can match the flow of music represented by an externally input musical tone signal and can provide an effect according to the user's preference.
[0005]
[Means for Solving the Problems]
  An effect imparting device according to an aspect of the present invention includes external music signal input means for inputting a music signal from outside,CorrespondingTempo designating means for designating the tempo is also provided. This tempo designating means can extract the tempo from the musical tone signal, or the user can listen to the musical tone signal and designate the tempo. The effect applying apparatus further outputs a signal having a period corresponding to the tempo specified by the tempo specifying means.repetitionPeriodic signal generating means for generating is provided. The effect applying apparatus further includes an envelope parameter setting unit that can arbitrarily set a plurality of types of parameters that define the shape of the envelope waveform. As the multiple types of parameters, for example, when the envelope waveform is composed of a plurality of sections, the length of each section is set, and in addition to this, the gradient in one or more predetermined sections of each section or A value at the boundary with the predetermined section can also be set. Determined by the parameters set by the envelope parameter setting means.Envelope waveform with shape,The periodic signal generated by the periodic signal generating meansDepending onEnvelope waveform generation means to generate repeatedlyIs provided.There is also provided effect applying means for applying an effect to the musical sound signal input to the external musical sound signal input means based on the envelope waveform. The effect imparting means may be various means such as a tone signal level changing means, a tone signal filtering means, a tone signal pitch changing means, or a tone signal flanger means.The effect applying apparatus includes a switching unit that switches the effect applying unit to an effect applying state or an effect non-applying state at an arbitrary timing, and for switching from the effect non-applying state to the effect applying state by the switching unit. In response, resetting the periodic signal resets the generation of the envelope waveform.
[0006]
  In this effect applying device, since the envelope waveform that defines the application state of the effect applied to the musical sound signal has a period corresponding to the tempo of the musical sound signal, the effect applied to the musical sound signal is Is repeatedly given. Moreover, since the shape of the envelope waveform is set in advance by the user using a plurality of types of parameters, an effect according to the user's preference can be imparted.Furthermore, since the generation of the envelope waveform is reset by resetting the periodic signal, an effect corresponding to the tempo can be given to the musical sound signal from the time of reset. At the time of resetting, since it is determined by switching from the effect non-application state to the application state of the switching means, the effect can be applied at an arbitrary timing.
[0011]
  In the effect imparting device according to another aspect of the present invention, as in the above-described aspect, an external musical tone signal input means, a tempo designation means, a periodic signal generation means, an envelope parameter setting means, an envelope waveform generation means, And an effect imparting means. Furthermore, the effect imparting device of another aspect is:Switching instruction means for instructing to switch the effect applying means to an effect applying state or an effect non-applying state at an arbitrary timinghave. Furthermore, the effect applying apparatus according to another aspect is the periodic signal generated by the periodic signal generating unit or the envelope waveform generating unit after the switching instruction unit instructs the switching from the non-effect applying state to the effect applying state. Switching means is also provided for switching to the effect imparting state when the envelope waveform generated by the device enters a predetermined state.As the predetermined state, for example, the phase of the periodic signal or the envelope waveform may be a predetermined phase, for example, an initial phase.
[0012]
With this configuration, even when a switching instruction is given, the effect is automatically applied when the periodic signal or the envelope waveform subsequently enters a predetermined state.
[0016]
  The effect applying apparatus according to another aspect of the present invention also includes an external musical tone signal input means, a tempo specifying means, a periodic signal generating means, an envelope parameter setting means, an envelope waveform generating means, and an effect applying means. Yes.Furthermore, in the effect imparting device of another aspect, the plurality of types of parameters that can be set by the envelope parameter setting means include a parameter relating to the time length of the envelope waveform. When the time length of the entire envelope waveform set in relation to the parameter related to the time length of the envelope waveform is longer than the period of the periodic signal, the envelope waveform generating means is configured to generate the envelope waveform for each period of the periodic signal. Is regenerated to change the time length of the entire envelope waveform to match the period of the periodic signal.
[0017]
In this case, the actually formed envelope waveform is different from that set by the envelope parameter setting means, and an effect different from that assumed can be imparted.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
The effect imparting device according to one embodiment of the present invention has external musical tone signal input means, for example, an input terminal 2, as shown by a functional block diagram in FIG. A continuous tone signal from the outside supplied to the input terminal 2 is supplied to switching means, for example, a contact 4a of the effect changeover switch 4.
[0019]
The effect changeover switch 4 has contacts 4b, 4c, and 4d, and the contact 4a can contact any of the contacts 4b, 4c, and 4d. In a normal state, the contact 4a contacts the contact 4c. However, the contact 4b or 4d is contacted by the operation of the switching instruction means, for example, the effect on / off operation element 6. However, the contact with the contact 4d is maintained only while the operation element 6 is operated. When the operation of the effect on / off operation element 6 is stopped, the contact state with the contact 4c is automatically restored.
[0020]
The contact 4 c is connected to the mixer 10 via the variable resistor 8. Therefore, in a state where the contact 4a is in contact with the contact 4c, the musical sound signal is output to the mixer 10 without any effect. The contacts 4 b and 4 d are connected to effect applying means, for example, a cascade connection circuit of the cutoff frequency variable filter 12 and the level control unit 14. The output of this cascade connection circuit is supplied to the mixer 10 via the variable resistor 16. Therefore, when the contact 4a is in contact with the contact 4b or 4d, a musical sound signal with an effect is supplied to the mixer 10. The values of the variable resistors 8 and 10 are adjusted by operating the balance operator 18.
[0021]
The cutoff frequency variable filter 12 is a low-pass filter whose cutoff frequency changes in accordance with a control signal supplied thereto. Of course, instead of the low pass filter, a high pass filter or a band pass filter may be used.
[0022]
The level control unit 14 controls the level of the input tone signal in accordance with a control signal supplied thereto, for example, an envelope waveform signal. Note that the effect applying means may be any means as long as it applies an effect to the musical tone signal, and various devices other than the cutoff frequency variable filter 12 and the level control unit 14 can be employed. For example, one that changes the pitch of the musical sound signal or one that imparts a flange effect to the musical sound signal can be employed.
[0023]
A control signal to the cutoff frequency variable filter 12 is supplied from the adder 20. The adder 20 has a waveform signal having a cycle T ′ generated by the waveform generator 24 based on a low-frequency pulse signal having a cycle T ′ oscillated by a low-frequency oscillator (LFO) 22 as a first control signal. Is supplied. The waveform of the waveform signal is a single waveform selected by the waveform selection operator 26 from among a plurality of waveforms, for example, a sawtooth wave, a trapezoidal wave, and a triangular wave.
[0024]
In the path of the waveform signal to the adder 20, an open / close switch 30 that is opened and closed by an LFO on / off operator 28 and a variable resistor 34 that is operated by an LFO depth operator 32 are provided. When the open / close switch 30 is on, the waveform signal is supplied from the waveform generator 24 to the adder 20, but when the open / close switch 30 is off, the waveform signal from the waveform generator 24 is not supplied to the adder 20. Further, the modulation depth applied by the cutoff frequency variable filter 12 is adjusted by the operation of the LFO depth operator 32.
[0025]
The adder 20 is supplied with an envelope waveform signal described later as the second control signal. When this envelope waveform signal is supplied to the adder 20 and the LFO on / off switch 30 is turned on, the sum of the waveform signal from the waveform generator 24 and the envelope waveform signal is sent to the filter 12 as a control signal. Supplied as When the envelope waveform signal is supplied to the adder 20 and the LFO on / off switch 30 is off, only the envelope waveform signal is supplied to the cutoff frequency variable filter 12 as a control signal. Further, when the LFO on / off switch 28 is on in a state where the envelope waveform signal is not supplied to the adder 20, only the waveform signal from the waveform generator 24 is supplied to the filter 12 as a control signal.
[0026]
The level controller 14 is supplied with an envelope waveform signal from the envelope generator 36 when the contact 38a of the changeover switch 38 is in contact with the contact 38b. When the contact 38a of the changeover switch 38 is in contact with the contact 38c, the envelope waveform signal is supplied to the adder 20 as described above. When the contact 38a of the changeover switch 38 is in contact with the contact 38d, no envelope waveform signal is supplied. The contact 38a is switched by operating the control target selection operator 40.
[0027]
The envelope generator 36 measures the elapsed time from that point in accordance with one pulse signal supplied from the low frequency oscillator (LFO) 42, and generates an envelope waveform signal as shown in FIG. To do. Since the pulse signal is repeatedly supplied from the LFO 42, in other words, the low frequency pulse signal is supplied, so that the envelope waveform signal is repeatedly generated as shown in FIG. The period T of the envelope waveform signal is determined based on the low frequency pulse signal generated by the LFO 42. The envelope waveform signal is defined by an attack time T1, a decay time T2, a sustain time T3, a release time T4, an attack level max, and a sustain level L1. The attack level max is a predetermined fixed value, and signals having values representing the attack time T1, the decay time T2, the sustain time T3, and the sustain level L1 are individually set by the envelope parameter operator 43.
[0028]
The signal having a value representing the release time T4 is subtracted from the signal representing the period T given from the multiplier 46, which will be described later, by the arithmetic unit 44, respectively, from the signals representing the attack time T1, the decay time T2, and the sustain time T3. And is supplied to the envelope generator 36. Therefore, it is not necessary to set all the times T1 to T4 one by one, and one of the four times is automatically set, so that the setting operation is simplified. Although the attack level max is a fixed value, it may be configured to be arbitrarily set by operating the envelope parameter operator 43.
[0029]
The LFO 22 generates a low frequency pulse signal with a period T ′ equal to the period T ′ indicated by the signal T ′ having a value indicating the period supplied from the multiplier 45. The LFO 42 generates a low frequency pulse signal with a period equal to the period T indicated by the signal T having a value indicating the period supplied from the multiplier 46. These LFOs 22 and 42 are simultaneously reset when the contact 4a of the changeover switch 4 is brought into contact with the contact 4b or 4d, and immediately generate a periodic signal having a period T ′ and T from a predetermined phase, for example, the initial phase 0, respectively. To start. That is, the first pulse is generated at the time of resetting, and thereafter, the pulse is repeatedly generated at T ′ and T.
[0030]
Both the multipliers 45 and 46 are supplied with a signal having a value indicating the period from the period conversion unit 48. In the multiplier 45, the signal having a value indicating the period is added to the length of the note selected by the note selection unit 50, such as a quarter note, a half note, an eighth note, a sixteenth note, etc. Is multiplied by a coefficient representing the one selected by, and a signal having a value indicating the period T ′ is generated and supplied to the LFO 22. Similarly, the multiplier 46 multiplies the signal having the value indicating the period from the period converting unit 48 by the coefficient indicating the length of the note selected by the note selecting unit 52 and has a value indicating the period T. A signal is generated and supplied to the LFO 22. Therefore, depending on the operation of the note selection operators 50 and 52, the periods T 'and T may be equal, or one may be several times the other.
[0031]
The period conversion unit 48 generates a signal having a value indicating the period based on the tempo signal from the tempo setting unit 54. When the open / close switch 58 is turned on by the operation of the tempo changing operation unit 56, the tempo setting unit 54 generates a tempo signal representing the tempo extracted from the musical tone signal supplied from the tempo extraction unit 60 to the input terminal 2. This is supplied to the period conversion unit 48. Further, when the open / close switch 58 is turned off, the tempo signal generated by operating the tap button 62 while the user listens to the musical sound signal supplied to the input terminal 2 is converted into a cycle conversion unit. 48. Accordingly, the period T ′, T of the periodic signal generated by the LFOs 22, 42, and the period of the waveform signal generated by the waveform generator 24 and the period of the envelope waveform signal generated by the envelope generator 36 are both supplied to the input terminal 2. This is based on the tempo of the tone signal to be played.
[0032]
The tempo signal from the tempo setting unit 54 is supplied to the tempo display unit 62, and the set tempo is displayed. The tempo signal is supplied to the tempo clock generator 64. The tempo clock signal generated here is supplied to the outside as a MIDI signal.
[0033]
In FIG. 1, the effect applying device is shown as a functional block diagram, but may be configured based on a DSP, a CPU, and each operator.
[0034]
According to the effect applying device configured as described above, when a musical sound signal is supplied to the input terminal 2, a tempo signal is generated by the tempo extracting unit 60 or by operating the tap switch 62. The tempo signal is converted into a signal having a value indicating the period by the period conversion unit 48 and supplied to the multipliers 45 and 46. The signal having a value indicating the period is multiplied by a coefficient indicating the length of the note selected by the operation of the note selection operator 50 in the multiplier 45, thereby generating a signal T ′ indicating the period T ′. This signal T ′ is supplied to the LFO 22, and the LFO 22 generates a low frequency pulse signal having a period T ′. This is supplied to the waveform generator 24. The waveform generation unit 24 generates a waveform signal having this cycle T ′ and having a waveform selected by the waveform selection operator 26. Since the LFO 22 repeatedly generates a pulse signal, this waveform signal is also repeatedly generated.
[0035]
When the open / close switch 30 is on, the level of this waveform signal is adjusted by the variable resistor 34 and supplied to the adder 20. At this time, if the envelope waveform signal is not supplied to the adder 20, this waveform signal is supplied to the cutoff frequency variable filter 12. When a musical tone signal is supplied to the filter 12 by the operation of the changeover switch 4, the musical tone signal is repeatedly modulated. Since the period of the waveform signal corresponds to the tempo of the musical sound signal, modulation is applied in accordance with the music flow. If an envelope waveform signal is also supplied, modulation is applied based on a signal obtained by adding the waveform signal and the envelope waveform signal. Note that multiplication may be performed instead of addition.
[0036]
The signal having a value indicating the period of the period converting unit 48 is multiplied by a coefficient indicating the length of the note selected by the note selecting unit 52 in the multiplier 46 to generate a signal having a value indicating the period T. , Supplied to the LFO 42. The LFO 42 supplies a low-frequency pulse signal having a period T to the envelope generation unit 36. The envelope generation unit 36 is supplied with T1, T2, T3, and L1 from the envelope parameter operator 43, and is supplied with T4 from the calculation unit 44. The envelope generator 36 repeatedly generates an envelope waveform signal defined by T1, T2, T3, T4, L1, and max with a period T.
[0037]
When the contact 38a of the changeover switch 38 is brought into contact with the contact 38b by the control target selection operator 40, the envelope waveform signal is supplied to the level control unit 14. The level of the output signal of the cutoff frequency variable filter 12 is controlled according to this envelope waveform signal. Accordingly, an envelope that matches the flow of the input tone signal is added to the tone signal.
[0038]
When the contact 38a of the changeover switch 38 is in contact with the contact 38c, the envelope waveform signal is supplied to the adder 20 and used for controlling the cutoff frequency variable filter 12. That is, when the open / close switch 30 is off, the cutoff frequency of the variable cutoff frequency filter 12 is varied only by the envelope waveform signal. Accordingly, the cutoff frequency of the cutoff frequency variable filter 12 is varied by the envelope waveform set according to the user's preference. When the open / close switch 30 is on, the cut-off frequency of the variable cut-off frequency filter 12 is varied by the added value of the envelope waveform signal and the waveform signal.
[0039]
When the contact 4a of the changeover switch 4 is brought into contact with the contact 4b by the operation of the effect on / off operation element 6, this contact state is maintained until the effect on / off operation element 6 is operated next. The musical tone signal is continuously supplied to the cutoff frequency variable filter 12, and the above-described effects are given to the musical tone signal. On the other hand, the contact 4a of the changeover switch 4 comes into contact with the contact 4d only during the period when the effect on / off operation member 6 is operated, and automatically returns to the contact state with the contact 4c when the operation is stopped. To do. Therefore, an effect is given to the musical sound signal only during the period when the effect on / off operation element 6 is operated so that the contact element 4a contacts the contact point 4d.
[0040]
When the contact 4a of the changeover switch 4 contacts the contact 4b or 4d, a reset signal is simultaneously supplied to the LFOs 22 and 42, and the LFOs 22 and 24 simultaneously generate new low frequency pulse signals. Therefore, both the low frequency pulse signals are synchronized, and the envelope waveform signal is also synchronized with the waveform signal. As shown in FIG. 4A, a new envelope waveform is generated from the time when the effect on instruction is given. appear. When the contact 4a of the changeover switch 4 comes into contact with the contact 4c, the application of the effect is stopped.
[0041]
Note that actual values are set as the parameters T1, T2, T3, and L1 set by the envelope parameter operator 43. Therefore, as shown in FIG. 5A, it is possible to set a time longer than the cycle T as T1. In this case, since the LFO 42 generates a new pulse signal when the period T elapses, unlike the assumed waveform having the attack, decay, sustain, and release as shown in FIG. A wave can be generated.
[0042]
Alternatively, as shown in FIG. 5B, it is possible to set T1 to be substantially 0, T2 to be larger than the period T, and L1 to be smaller than max. Also in this case, unlike the assumed waveform of FIG. 2, it is possible to generate a trapezoidal wave whose value increases to max as soon as it occurs, decreases as time elapses, and decreases to 0 when the period T elapses. In this state, when L1 is changed to almost 0, a sawtooth wave that falls with time can be generated.
[0043]
Similarly, as shown in FIG. 2C, when T3 is set to 0, T1 + T2 is set to be smaller than T, and L1 is set equal to max, unlike the assumed waveform in FIG. The value is 0, the value increases as time elapses, the value becomes max when T1 time elapses, this value is maintained for time T2, and thereafter the value decreases as time elapses, and becomes 0 when time T4 elapses. A trapezoidal wave can be generated.
[0044]
Thus, an envelope waveform signal different from the assumed waveform can be generated by setting the envelope parameter. It should be noted that a settable range of T1, T2, T3, and L1 may be determined in advance to always include the attack, decay, sustain, and release sections. As the envelope parameter setting method, in addition to the method of setting the real time of T1 to T3 as described above, the method of setting the ratio of T1 to T3 with respect to the period T, or the attack period instead of T1 and T2 It is also possible to set the slope of the period and the slope of the decay period. When setting the gradient, since max is a fixed value, T1 and T2 are also automatically determined by setting the gradient of the attack period and the gradient of the decay period.
[0045]
  In the above embodiment, the envelope waveform has four sections of attack, decay, sustain, and release.In FIG.As shown, it may have three sections of attack (T1), decay (T2), and release (T3). In this case, in order to simplify the setting, only T1, T2, and L1 can be set, and T3 can be calculated by T-T1-T2 calculation by the calculation unit.
[0046]
In the above embodiment, the phase of the LFOs 22 and 42 is reset when the effect on / off operator 6 is instructed to switch the effect application from the off state to the on state. It can also be reset by means. For example, when extracting the tempo from an externally input musical sound signal, the tempo extraction unit 60 extracts the start of the beat in addition to the tempo, and extracts the tempo while the open / close switch 58 is on. A signal indicating the start of a beat is supplied to the LFOs 22 and 42. In this way, the phases of the LFOs 22 and 42 can be reset in synchronization with the beat of the musical tone signal input from the outside.
[0047]
In the above embodiment, the phase of the LFOs 22 and 42 is reset when the effect on / off operation element 6 is operated to instruct the effect to be switched from the off state to the on state. It is also possible to provide a control mode and to select a desired control mode from a plurality of control modes.
[0048]
For example, the control mode described in the above embodiment is set as the first control mode, and in addition to this, the second control mode and the third control mode described below are provided, and any control mode is arbitrarily set. select.
[0049]
In the second control mode, the reset signal is not supplied to the LFOs 22 and 42 even if the effect on / off operation element 6 instructs to switch the effect application from the off state to the on state. Further, even if the effect on / off operation element 6 is used to instruct the effect to be switched from the off state to the on state, the contact 4a of the changeover switch 4 remains in contact with the contact 4c, and the low frequency pulse generated by the LFO 22 or LFO 42 is maintained. The phase detection means detects that the signal phase is the initial phase, that is, the same phase as when it was reset, and when this is detected, the contact 4a of the changeover switch 4 is brought into contact with the contact 4b or 4d. . Therefore, even if the LFOs 22 and 42 are instructed to switch the effect applying state to the on state, the LFOs 22 and 42 still maintain the state before the instruction, and similarly, the envelope generation unit 36 is also in the state before the effect applying state is switched to the on state. Keep. Then, when the phase of the low frequency pulse signal generated by the LFO 22 or the LFO 42 becomes the initial phase, the application of the effect is started for the first time as shown in FIG.
[0050]
Accordingly, the effect can be started in synchronization with the phase of the low-frequency pulse signal without resetting the phase of the low-frequency pulse signal generated by the LFO 22 or 42. Even if the operation is performed at rough timing, the effect can be started in synchronization with the musical tone signal.
[0051]
Instead of setting the time when the contact 4a of the change-over switch 4 is brought into contact with the contact 4b or 4d as the time when the phase of the low-frequency pulse signal generated by the LFO 22 or LFO 42 becomes the initial phase, the envelope generator 36 Even if the level detection unit detects that the generated envelope waveform signal has reached a predetermined level, for example, 0, and the contact 4a is brought into contact with the contact 4b or 4d when this is detected, the same operation as described above can be performed. . Further, when the envelope generation unit 36 measures the elapsed time from the input of the pulse signal and generates an envelope waveform signal, the time point when the detection unit detects that the elapsed time has reached a predetermined value Even if the changeover switch 4 is switched, the same operation can be performed.
[0052]
In the third control mode, similarly to the second control mode, even if the effect on / off operation element 6 instructs the effect to be switched from the off state to the on state, no reset signal is supplied to the LFOs 22 and 42. However, unlike the second control mode, in the third control mode, as shown in FIG. 4C, immediately after the effect on / off operation element 6 is instructed to switch the effect application from the off state to the on state. Then, start giving the effect.
[0053]
In any control mode, when the effect on / off operation element 6 instructs to switch the effect from the on state to the off state, as shown in FIGS. 4 (b) and 4 (c), the effect is imparted. To stop.
[0054]
【The invention's effect】
  As described above, according to the effect imparting device of the present invention, it is possible to repeatedly impart an effect according to the user's preference that matches the flow of the musical sound signal.it can. Also,Switching from the effect imparting state to the imparting state of the switching means can be performed at any timing, and the envelope waveform signal is reset by this switching, so that the effect can be imparted at any timing. Similarly, even if the timing for giving the switching instruction is not the timing at which the periodic signal or envelope waveform is in a predetermined state, the effect can be automatically applied when the periodic signal or envelope waveform is in the predetermined state. Even if a switching instruction is given at a rough timing, the effect application can be started in synchronization with the musical tone signal.Furthermore, actuallyThe formed envelope waveform can be different from that set by the envelope parameter setting means, and can give an effect different from that assumed.
[Brief description of the drawings]
FIG. 1 is a block diagram of an effect applying device according to an embodiment of the present invention.
2 is a waveform diagram showing one cycle of an envelope waveform signal generated by the effect applying device of FIG. 1; FIG.
FIG. 3 is a waveform diagram showing a plurality of periods of an envelope waveform signal generated by the effect applying device of FIG. 1;
4 is a diagram showing the timing of effect application and stop in the effect adding device of FIG. 1; FIG.
5 is a waveform diagram of the envelope waveform signal of FIG. 3 when various values of parameters are changed.
6 is a waveform diagram of another example of an envelope waveform signal generated by the effect applying device of FIG. 1. FIG.
[Explanation of symbols]
2 Input terminals (external music signal input means)
12 Cut-off frequency variable filter (effect applying means)
14 Level control unit (means for giving effect)
22 LFO (periodic signal generating means)
36 Envelope generator (envelope waveform generator)
43 Envelope parameter operator (envelope parameter setting means)
42 LFO (periodic signal generating means)
54 Tempo setting section (tempo designation means)

Claims (3)

An external musical sound signal input means for inputting a musical sound signal from the outside;
Tempo designating means for designating a tempo corresponding to the musical sound signal;
Periodic signal generating means for repeatedly generating a signal having a period corresponding to the tempo specified by the tempo specifying means;
An envelope parameter setting means capable of arbitrarily setting a plurality of types of parameters for determining the shape of the envelope waveform;
An envelope waveform generating means for repeatedly generating an envelope waveform having a shape determined by the respective parameters set by the envelope parameter setting means according to the periodic signal generated by the periodic signal generating means;
An effect applying means for applying an effect to the musical sound signal input to the external musical sound signal input means based on the envelope waveform;
An effect providing device comprising :
Switching means for switching the effect applying means to an effect applying state or an effect non-applying state at an arbitrary timing;
The effect applying device that resets generation of the envelope waveform by resetting the periodic signal in response to switching from the effect non-applying state to the effect applying state by the switching unit. An external musical sound signal input means for inputting a musical sound signal from the outside;
Tempo designating means for designating a tempo corresponding to the musical sound signal;
Periodic signal generating means for repeatedly generating a signal having a period corresponding to the tempo specified by the tempo specifying means;
  An envelope parameter setting means capable of arbitrarily setting a plurality of types of parameters for determining the shape of the envelope waveform;
An envelope waveform generating means for repeatedly generating an envelope waveform having a shape determined by the respective parameters set by the envelope parameter setting means according to the periodic signal generated by the periodic signal generating means;
An effect applying means for applying an effect to the musical sound signal input to the external musical sound signal input means based on the envelope waveform;
An effect providing device comprising:
Switching instruction means for instructing to switch the effect applying means to an effect applying state or an effect non-applying state at an arbitrary timing;
The periodic signal generated by the periodic signal generating means or the envelope waveform generated by the envelope waveform generating means is in a predetermined state after the switching instruction means instructs the switching from the effect non-applying state to the effect applying state. Switching means for switching to the effect imparting state when
An effect imparting device. An external musical sound signal input means for inputting a musical sound signal from the outside;
Tempo designating means for designating a tempo corresponding to the musical sound signal;
A periodic signal generation means for repeatedly generating a periodic signal having a period corresponding to the designated tempo by the tempo specifying means,
An envelope parameter setting means capable of arbitrarily setting a plurality of types of parameters for determining the shape of the envelope waveform;
An envelope waveform generating means for repeatedly generating an envelope waveform having a shape determined by the respective parameters set by the envelope parameter setting means according to the periodic signal generated by the periodic signal generating means;
An effect imparting device comprising effect imparting means for imparting an effect to the musical sound signal input to the external musical sound signal input means based on the envelope waveform,
The plurality of types of parameters that can be set by the envelope parameter setting means include a parameter relating to the time length of the envelope waveform,
When the time length of the entire envelope waveform set in relation to the parameter related to the time length of the envelope waveform is longer than the period of the periodic signal, the envelope waveform generating means is configured to generate the envelope waveform for each period of the periodic signal. The effect imparting device that changes the time length of the entire envelope waveform so as to match the period of the periodic signal by regenerating .

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