DE4133469A1 - Acoustic signal synthesiser e.g. for music - Google Patents

Abstract

The synthesiser generates acoustic data representing sounds e.g. ROMS (1-3). An envelope-generator (CR4-CR6) generates a number of envelope signals each corresponding to one of the sounds, and digital-to-analog converters (20-22) convert the acoustic data from digital to analog form. Envelope-processors envelope-process acoustic data representing each of the sounds in response to the envelope signals. The digital-to-analog converters and envelope-processors are arranged to generate envelope-processed analog signals each corresponding to one of the sounds, and a mixing circuit (23) combines the analog signals to produce a combined acoustic output signal.

Description

The invention relates to a device for generating art Licher acoustic signals, that is, to generate artificial sounds like music.

Such a device for generating artificial acousti sher signals is for example in JP-A-59-26 789 of fenbart. When a sound is generated, changes with as time progresses, its timbre in general nig. Because especially high frequency components in the sound be attenuated significantly while low frequency components only subject to slight damping changes the state (timbre) of the sound a little over time. Therefore, are described in the aforementioned document system, three types of acoustic data are specified, wel che correspond to different signal forms, namely the Waveform for the timbre of a sound immediately after its generation, the signal form for the timbre, after which has passed a certain time after the sound has been generated is, so that the sound is dampened accordingly, or the Waveform for the timbre after a lapse another certain period of time so that the sound corresponds is dampened more. This acoustic data will be previously stored in three memory circuits (ROMs). Then the signals of the three sounds to be generated are sequential other using the three types of acoustic data mo the resulting output signals are digi tal added together and the resulting out  The output signal is converted digitally / analogously and is used modified an envelope signal. In the result are the three sounds combined into one.

For example, in the described artificial sound producing system, when a melody is generated by generating a first tone C at a time T 1 , a second tone B at a time T 2 , overlapping each other, and a third tone A at a time T 3 , . also overlapping, as shown in FIG 5 is assembled, the following is observed: Although the first sound C decreases and has immediately before the generation of the second sound B Am plitude c 1, he takes an amplitude c 2 immediately after the Erzeu supply of second tone B. This effect is due to the embossing of an envelope signal on the tones B and C. Namely, since the envelope signal is applied when the second tone B is generated so that a maximum amplitude occurs, the amplitude of the first tone C is suddenly increased to c2 instead of being or remaining c1. In other words, since each tone produced is treated as if it were subjected to a predetermined attenuation, regardless of whether it lasts long or short, the amplitude is increased suddenly from c1 to c2 in the example according to FIG. 5; thus a listener can only perceive a discontinuous or non-organic sound. When the third tone A is generated, it is added to the already damped tones B and C, which means that the third tone A is added to the tones B and C on the assumption that they are damped to a predetermined degree, independently the elapsed duration of the tones generated; Therefore, according to the example of FIG. 5, the sounds are added such that b1 is abruptly reduced to b2 and c3 is increased abruptly to c4, so that only a non-organic ge sound is stopped. Since the resultant composite sound is processed using a common envelope signal after the combination of several tones, the ratio of the volumes of the individual tones remains unchanged; thus the ratio of the volume of the individual tones is the same at all times. This results in very unnatural acoustics.

The object of the invention is therefore to make it possible to combine several tones in such a way that the tones are composed organically and continuously become, whereby an apparently natural acoustic syn thetization is achieved.

The stated object is achieved according to the invention with a front Direction according to claim 1 or 2 solved.

By using the envelope circuits, this is corresponding envelope signal together with the acoustic Generates data for a first tone; then together with the generation of acoustic data for a second Sound generates the corresponding envelope signal; it takes place the envelope processing, and at that time the first tone using the envelope signal is muted, combined with the second tone. When a third tone is generated, it will be the same third acoustic data corresponding envelope signal generated at the same time, and the first and the second tone, which using the appropriate envelopes signals have been attenuated at this time combined with the third tone. That way it will respective envelope curve signal corresponding to each acoustic Data is generated, and any sound that is made using the ent speaking envelope signal has been attenuated, while prevailing, combined with the others, thereby  get an apparently natural composite sound can be.

In the following, the invention is based on a preferred embodiment Example with reference to the attached drawing tion explained in more detail. Show it:

Fig. 1 is a block diagram of a first game Ausführungsbei of the invention;

Fig. 2 is a graph showing, in relation to the generation times of each tone, start signals which are supplied to the envelope circuits (CR) 4 , 5 and 6 , envelope signals which have been generated by the CRs 4 , 5 and 6 , the respective Link between the output connections and the input connections of a second selector 16 , and the respective connections between the output connections and the input connections of a first selector 8 shows;

Fig. 3 is a block diagram of a second embodiment of the invention;

Fig. 4 is a block diagram of a third embodiment of the invention; and

Fig. 5 is a signal diagram of the course of a sound that has been generated by a conventional device for generating artificial acoustic signals.

A first embodiment of the inven tion is explained with reference to FIGS . 1 and 2.

Referring to FIG. 1, memory circuits (ROM) 1, 2 and 3 for respectively storing different acoustic data (such as PCM data) are provided; For example, the acoustic data for the initial state of a sound, the acoustic data for a later state of the sound and the acoustic data for an even later state of the sound are stored in these memory circuits. The number of memory circuits is selected according to the number of tones to be combined. In this example, it is 3. In order to generate an envelope signal corresponding to the respective acoustic data in synchronism with the generation time of the respective acoustic data, several envelope circuits (CR) 4 , 5 and 6 are provided. Time signals T 1 , T 2 and T 3 according to FIG. 2 are each given by a control circuit 7 to a first input connection or T connection of the elements CR 4 , CR 5 and CR 6 . Time start signals a 1 , a 2 and a 3 are each given by the control circuit 7 to second input connections or A connections. Different envelope signals q 1 , q 2 and q 3 are supplied from the output connections Q of the CR's 4 , 5 and 6 to the start signals a 1 , a 2 and a 3 and to the time signals T 1 , T 2 and T 3 . The envelope signals q 1 , q 2 and q 3 from the CRs 4 , 5 and 6 are fed to input connections D 1 , D 2 and D 3 of a first selector 8 . The internal circuitry of the first selector 8 regarding its input connections D 1 , D 2 and D 3 and its output connections Q 1 , Q 2 and Q 3 is designed in accordance with the time signals T 1 , T 2 and T 3 by the control circuit 7 are submitted, as will be explained in more detail below.

Data corresponding to a frequency division ratio for determining the level of each tone (scale) of a melody to be generated is stored in a memory circuit (ROM) 9 . The memory circuit is controlled by the control circuit 7 in order to supply the division ratio data of a particular tone, the division ratio data being temporarily stored in one of the buffer circuits 10 , 11 and 12 , namely that which has received a buffer signal from the control circuit 7 . The number of latch circuits corresponds to the number of tones to be combined (3 in this example). A fundamental frequency signal F with a sufficiently high frequency is supplied to variable frequency dividers 13 , 14 and 15 , which are provided accordingly for the buffer circuits. The variable frequency dividers perform frequency division based on the division ratio data from the latch circuits 10 , 11 and 12 , respectively, and output clock signals for use in generating a desired pitch. The output signals of the variable frequency divider 13 , 14 and 15 are input terminals D 1 ', D 2 ' and D 3 'of a second selector 16 supplied. The internal connection of the second selector 16 regarding its input connections D 1 ', D 2 ' and D 3 'and its output connections Q 1 ', Q 2 'and Q 3 ' is in accordance with the time signals T 1 , T 2 and T 3 from the control circuit 7 designed, as this will be explained in more detail later.

The output signals at the output terminals Q 1 ', Q 2 ' and Q 3 'of the second selector 16 are counted in counters 17 , 18 and 19 in order to determine the respective addresses of the memory circuits (ROM) 1 , 2 and 3 . The output signals of the ROMs 1 , 2 and 3 are converted from digital to analog form in D / A converters 20 , 21 and 22 and processed simultaneously with an envelope, using the envelope signals from the output connections Q 1 , Q 2 and Q 3 of the first selector 8 .

The output signals of the D / A converters 20 , 21 and 22 are combined in a mixing circuit 23 and emitted by a loudspeaker 25 in the form of a sound, after which they have passed through an amplifier 24 .

The method of generating artificial acoustic signals is explained below with reference to FIG. 2.

Suppose a tone c produced at time T 1 is "c"("do") the length of a quarter of a beat, a tone B generated at a later time T 2 is "d"("re") the length of one half stroke and a tone A generated at a later time T 3 is "e"("mi") with the length of an eighth stroke. The method of combining these tones in sequence to produce a melody "cde"("do-remi") is explained below.

To generate the first tone C, the time signal T 1 is given by the control circuit 7 to the CRs 4 , 5 and 6 , the ROM 9 and the buffer circuit 10 . Accordingly, the division ratio data for determining the height of the tone "c"("do") is supplied from the ROM 9 and stored in the latch circuit 10 . The frequency signal F is frequency-divided in the variable frequency divider 13 to generate a clock signal for use in gaining the pitch of "c"("do"). This clock signal is fed to the terminal D 1 'of the second selector 16 . Since the internal connection of the second selector 16 with the time signal T 1 is such that Q 1 '= D 1 ', Q 2 '= D 3 ' and Q 3 '= D 2 ', the clock signal is sent to the counter 17 given. In response to the output signal of the counter 17 , the acoustic data corresponding to the initial state of "c"("do") are read out by the ROM 1 .

If the time signal T 1 is given by the control circuit 7 to the CRs 4 , 5 and 6 , the start signal a 1 is simultaneously given to CR 4 on the other side; therefore, the time the signal T 1 corresponding envelope signal is q 1 of the CR 4 generated and applied to the terminal D 1 of the first selector. 8 Since the internal connection of the first selector 8 , which is carried out by means of the time signal T 1 , is such that Q 1 = D 1 , Q 2 = D 3 and Q 3 = D 2 , the acoustic data are corresponding to the initial state of "c "(" do ") from the ROM 1 in the D / A converter 20 converted from the digital form into the analog form and simultaneously processed by means of an envelope, using the envelope signal q 1 corresponding to the time signal T 1 , which is output from terminal Q 1 of first selector 8 . The signal from the D / A converter 20 is sent to the loudspeaker 25 via the mixing circuit 23 and the amplifier 24 , where it is output in the form of a sound.

In order to generate the second tone B, the time signal T 2 is given by the control circuit 7 to the CRs 4 , 5 and 6 , the ROM 9 and the buffer circuit 11 . Accordingly, who the partial ratio data for determining the pitch of the tone "d"("re") is supplied by the ROM 9 and buffered in the latch circuit 11 . The frequency signal F is frequency-divided in the variable frequency divider 14 to generate a clock signal for use in determining the pitch of "d"("re"), which is supplied to the terminal D 2 'of the second selector 16 . Since the internal circuitry of the second selector 16 with the time signal T 2 is designed such that Q 1 '= D 2 ', Q 2 '= D 1 ' and Q 3 '= D 3 ', the clock signal from the input terminal D 2 'sent to the output terminal Q 1 ' and given to the counter 17 , the acoustic data corresponding to the initial state of "d"("re") are read from the ROM 1 , and the clock signal for use in determining the pitch of the first tones "c"("do"), which is supplied by the variable frequency divider 13 , is sent from the input terminal D 1 'to the output terminal Q 2 ' and output to the counter 18 , so that the acoustic data corresponding to the later state of "c"("do") can be read from the ROM 2 .

If the time signal T 2 is given by the control circuit 7 to the CRs 4 , 5 and 6 , the start signal a 2 is simultaneously given to CR 5 ; therefore, the time T 2 ent speaking envelope signal q generated in 2 CR 5 and applied to the terminal D 2 of the first selector. 8 Since the internal connection of the first selector 8 by means of the time signal T 2 is designed such that Q 1 = D 2 , Q 2 = D 1 and Q 3 = D 3 , the acoustic data are in accordance with the initial state of the second tone "d"("re" from the ROM 1 in the D / A converter 20 converted from the digital form into the analog form and simultaneously processed with an envelope, using the envelope signal q 2 corresponding to the time signal T 2 by the Output terminal Q 1 is given to the first selector 8. In addition, the acoustic data corresponding to a later state of the first tone "c"("do") from the ROM 2 in the D / A converter 21 from the digital to the converted analog form and simultaneously processed with an envelope using the envelope signal q 1 corresponding to the time signal T 2 , which is supplied by the output terminal Q 2 of the first selector 8. The signals from the D / A converters 20 and 21 are in the Mixing circuit 23 combines, which means that the tone "d"("re") that has just been generated and the tone "c"("do") that was generated a short time before are combined into one sound, so that the resulting composite sound from the speaker 25 is output in the form of audible signals after it has passed through the amplifier 24 .

In order to generate the third tone A, the time signal T 3 is given by the control circuit 7 to the CRs 4 , 5 and 6 , the ROM 9 and the buffer circuit 12 . Accordingly, the division ratio data for determining the pitch of the tone "e"("mi") is supplied from the ROM 9 and latched in the latch circuit 12 . The frequency signal F is divided frequency-wise in the variable frequency divider 15 in order to testify a clock signal for use in gaining the pitch of "e"("mi"), which is given to the terminal D 3 'of the second selector 16 . Since the internal connection of the second Se lector 16 is set by means of the time signal T 3 such that Q 1 '= D 3 ', Q 2 '= D 2 ', and Q 3 '= D 1 ', the clock signal for use when winning the pitch of the third tone "e"("mi") from the input terminal D 3 'to the output terminal Q 1 ' sent. The acoustic data corresponding to the initial state of "e"("mi") are read out from the ROM 1 by means of the counter 17 , at the same time the clock signal is used for obtaining the pitch of the second tone "d"("re") from that Input circuit D 2 'of the second selector 16 sent to the output terminal Q 2 ', the acoustic data corresponding to the later state of "d"("re") are read from the ROM 2 by means of the counter 18 , the clock signal for use when winning the pitch of the first tone "c"("do") is sent from the input terminal D 1 'of the second selector 16 to the output terminal Q 3 ', and the acoustic data corresponding to the later state of "c"(" do ") are read from the ROM 3 by means of the counter 19 .

If the time signal T 3 is given by the control circuit 7 to the CRs 4 , 5 and 6 , the start signal a 3 is simultaneously given to the CR 6 ; consequently, the envelope vensignal q 3 is generated in accordance with the time signal T 3 from the CR 6 and ben to the terminal D 3 of the first selector 8 . Since the internal connection of the first selector 8 is designed by means of the time signal T 3 such that Q 1 = D 3 , Q 2 = D 2 and Q 3 = D 1 , the acoustic data are corresponding to the initial state of the third tone "e"("mi") from the ROM 1 in the D / A converter 20 converted from digital to analog form and at the same time processed using an envelope signal Q 3 with an envelope which corresponds to that of the output terminal Q 1 of the first selek tors 8 delivered time signal D 3 corresponds. The signal of the second acoustic data corresponding to the later state of the second tone "d"("re") from the ROM 2 is converted in the D / A converter 21 from the digital to the analog form and simultaneously processed with an envelope, and that is, using the envelope signal q 2 corresponding to the time signal T 3 , which is supplied by the output terminal Q 2 of the first selector 8 . The signal of the acoustic data corresponding to the still later state of the first tone "c"("do") from the ROM 3 is converted in the D / A converter 22 from the digital form into the analog form and at the same time with an envelope processed, using the envelope signal q 1 corresponding to the time signal T 3 , which is output from the output terminal Q 3 of the first selector 8 . The signals of the D / A converters 20 , 21 and 22 are combined in the mixing circuit 23 , which means that the tone "e"("mi") that has just been generated, the tone "d"("re"), which had been generated shortly before, and the sound" c "(" do "), which had been generated a little before, were combined to form a sound, so that the resulting composite sound from the speaker 25 in Form of audible signals is output after it has passed through the amplifier 24 .

According to the structure shown in Fig. 1, described above, each tone is continuously output, being attenuated in accordance with the envelope signal which is generated in synchronism with its generation time from the time at which it is generated until the third tone is generated. Its amplitude never rises or falls suddenly. Since the three envelope signals are generated in accordance with the three tones to be combined in synchronism with the generation time of these tones or sounds, an apparently natural composite sound can be obtained.

A second embodiment shown in Fig. 3 differs from the first embodiment in the fact that the second selector has continued to stand for 16. While according to the first embodiment, the latch circuits 10 , 11 and 12 are parallel to the ROM 9 , latch circuits 27 , 28 and 29 are in series with a ROM 26 , the output signals of these latch circuits learning the corresponding variable frequency divider 13 , 14 and 15 as supplied according to the first embodiment. Each time the control circuit 7 is driven, the output signal is given to all the latch circuits 27 , 28 and 29 simultaneously. The output signal of the variable frequency divider 13 is given directly to the counter 17 , the output signal of the frequency divider 14 to the counter 18 and the output signal of the frequency divider 15 to the counter 19 . Otherwise, the structure is identical to that of the first exemplary embodiment.

Therefore, when the division ratio data of the first tone C is latched in the latch circuit 27 and the division ratio data of the second tone B is supplied from the ROM 26 , this data is latched in the latch circuit 27 , while the division ratio data of the first tone C is latched in the latch circuit 28 will. Similarly, when the division ratio data of the third tone A is supplied from the ROM 26 , this data is stored in the latch circuit 27 , while the division ratio data of the second tone B in the latch circuit 28 and the division ratio data of the first tone C. can be temporarily stored in the buffer circuit 29 . Therefore, no second selector is required. The acoustic data corresponding to the initial state of a tone are thus always to the D / A converter 20 , the acoustic data corresponding to the later state of the tone to the D / A converter 21 and the acoustic data corresponding to the later state of a tone given to the D / A converter 22 . The remaining processing is identical to that described in connection with the first embodiment.

A third embodiment shown in FIG. 4 differs from the second embodiment in that lecturer as the selector 8 of the second embodiment by a Se 30 is replaced, between the ROMs 1, 2 and 3 and the D / A converters 20, 21 and 22 lies. Therefore, the output signals of the CRs 4 , 5 and 6 are given directly to the D / A converters 20 , 21 and 22, respectively. The internal connection of the selector 30 with regard to its input connections D 1 '', D 2 '' and D 3 '' and its output connections Q 1 '', Q 2 '' and Q 3 '' is identical to that of the first embodiment table. Accordingly, the internal connection to the time signal T 1 such that Q 1 '' = D 1 '', Q 2 '' = D 3 '' and Q 3 '' = D 2 '', to the time signal T 2 such that Q 1 ′ ′ = D 2 ′ ′, Q 2 ′ ′ = D 1 ′ ′ and Q 3 ′ ′ = D 3 ′ ′, and on the time signal T 3 in such a way that Q 1 ′ ′ = D 3 '', Q 2 '' = D 2 '' and Q 3 '' = D 1 ''.

When the time signal T 3 is supplied, therefore, the acoustic data of the first tone C from the ROM 3 to the input terminal D 3 '' of the selector 30 and then from the output terminal Q 1 '' to the D / A converter 20 are given , where they are converted from the digital form into the analog form and processed with an envelope using the envelope signal q 1 corresponding to the time signal T 3 , which is output by the CR 4 . The data of the second tone B are given from the ROM 2 to the input terminal D 2 '' of the selector 30 and then from the output terminal Q 2 '' to the D / A converter 21 , where they change from the digital form to the analog form converted and processed by means of an envelope, using the envelope signal nals q 2 in accordance with the time signal T 3 , which is output by the CR 5 . Furthermore, the data of the third tone A from the ROM 1 to the input terminal D 1 '' of the selector 30 and then from the output terminal Q 3 '' to the D / A converter 22 , where they are given from the digital form to the analog Form converted and processed by means of an envelope, using the envelope signal q 3 accordingly the time signal T 4 , which is output by the CR 6 .

If the selector between the ROMs and the D / A converters is arranged as described above, it is sufficient that the Se is able to transmit digital signals gene; thus the circuit structure can be made simpler be considered the one responsible for transmitting analog signals be able to. The other processing is the same some identical in connection with the first execution Example have been described.

Although the processing with the envelope at the same time the digital-to-analog conversion in the version described examples, it can also be based on the digital Analog conversion can be made.

In the generating device described above artificial acoustic signals according to the invention correspond to several different acoustic data blocks according to the initial state, a later state, one later state etc. of a tone to be generated  ago stored, the respective envelope signals corresponding to the tones in sync with the generation time ei nes each tone are generated, and all acoustic Data is processed with an envelope, namely un ter using the corresponding envelope signal; therefore the resulting composite sound is organic and continuously, even in the case of artificial production licher acoustic signals, which is why seemingly natural Artificial acoustic signals can be generated.

The in the above description, the claims as well Features of the invention disclosed in the drawing both individually and in any combination for the Realization of the invention in its various embodiments forms are essential.

Claims (2)

1. A device for generating artificial acoustic signals, comprising:
several memory circuits ( 1 , 2 , 3 ) in which different acoustic data are stored,
a plurality of envelope circuits ( 4 , 5 , 6 ) for generating an envelope signal in each case in accordance with the acoustic data, specifically in synchronism with the generation time of the acoustic data,
a plurality of D / A converters ( 20 , 21 , 22 ) for converting the acoustic data from the individual memory circuits ( 1 , 2 , 3 ) from the digital to the analog form and for carrying out envelope processing, using the envelope signal from the respective envelope circuit ( 4 , 5 , 6 ), according to the acoustic data,
a selector ( 8 ) for outputting the envelope signals from the individual envelope circuits ( 4 , 5 , 6 ) to the D / A converter ( 20 , 21 , 22 ) to which the corresponding acoustic data are output, and
a mixing circuit ( 23 ) for combining the respective output signals of the D / A converter ( 20 , 21 , 22 ) with one another. 2. Device for generating artificial acoustic signals, comprising:
several memory circuits ( 1 , 2 , 3 ) in which different acoustic data are stored,
a plurality of envelope circuits ( 4 , 5 , 6 ) for generating an envelope signal in each case in accordance with the acoustic data, specifically in synchronism with the generation time of the acoustic data,
a plurality of D / A converters ( 20 , 21 , 22 ) for converting the acoustic data from the individual memory circuits ( 1 , 2 , 3 ) from the digital to the analog form and for carrying out envelope processing, using the envelope signal from the respective envelope switch ( 4 , 5 , 6 ), according to the acoustic data,
a selector ( 30 ) for outputting the acoustic data from the memory circuits ( 1 , 2 , 3 ) to the D / A converter ( 20 , 21 , 22 ) to which the envelope signals are output in accordance with the acoustic data, and
a mixing circuit ( 23 ) for combining the respective output signals of the D / A converter ( 20 , 21 , 22 ) with one another.