Classifications

• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04M—TELEPHONIC COMMUNICATION
  • H04M19/00—Current supply arrangements for telephone systems
  • H04M19/02—Current supply arrangements for telephone systems providing ringing current or supervisory tones, e.g. dialling tone or busy tone
  • H04M19/04—Current supply arrangements for telephone systems providing ringing current or supervisory tones, e.g. dialling tone or busy tone the ringing-current being generated at the substations
  • H04M19/041—Encoding the ringing signal, i.e. providing distinctive or selective ringing capability
• • G—PHYSICS
  • G10—MUSICAL INSTRUMENTS; ACOUSTICS
  • G10H—ELECTROPHONIC MUSICAL INSTRUMENTS; INSTRUMENTS IN WHICH THE TONES ARE GENERATED BY ELECTROMECHANICAL MEANS OR ELECTRONIC GENERATORS, OR IN WHICH THE TONES ARE SYNTHESISED FROM A DATA STORE
  • G10H1/00—Details of electrophonic musical instruments
  • G10H1/18—Selecting circuits
  • G10H1/24—Selecting circuits for selecting plural preset register stops
• • G—PHYSICS
  • G10—MUSICAL INSTRUMENTS; ACOUSTICS
  • G10H—ELECTROPHONIC MUSICAL INSTRUMENTS; INSTRUMENTS IN WHICH THE TONES ARE GENERATED BY ELECTROMECHANICAL MEANS OR ELECTRONIC GENERATORS, OR IN WHICH THE TONES ARE SYNTHESISED FROM A DATA STORE
  • G10H7/00—Instruments in which the tones are synthesised from a data store, e.g. computer organs
  • G10H7/02—Instruments in which the tones are synthesised from a data store, e.g. computer organs in which amplitudes at successive sample points of a tone waveform are stored in one or more memories
• • G—PHYSICS
  • G10—MUSICAL INSTRUMENTS; ACOUSTICS
  • G10H—ELECTROPHONIC MUSICAL INSTRUMENTS; INSTRUMENTS IN WHICH THE TONES ARE GENERATED BY ELECTROMECHANICAL MEANS OR ELECTRONIC GENERATORS, OR IN WHICH THE TONES ARE SYNTHESISED FROM A DATA STORE
  • G10H2230/00—General physical, ergonomic or hardware implementation of electrophonic musical tools or instruments, e.g. shape or architecture
  • G10H2230/005—Device type or category
  • G10H2230/021—Mobile ringtone, i.e. generation, transmission, conversion or downloading of ringing tones or other sounds for mobile telephony; Special musical data formats or protocols therefor
• • G—PHYSICS
  • G10—MUSICAL INSTRUMENTS; ACOUSTICS
  • G10H—ELECTROPHONIC MUSICAL INSTRUMENTS; INSTRUMENTS IN WHICH THE TONES ARE GENERATED BY ELECTROMECHANICAL MEANS OR ELECTRONIC GENERATORS, OR IN WHICH THE TONES ARE SYNTHESISED FROM A DATA STORE
  • G10H2230/00—General physical, ergonomic or hardware implementation of electrophonic musical tools or instruments, e.g. shape or architecture
  • G10H2230/025—Computing or signal processing architecture features
  • G10H2230/031—Use of cache memory for electrophonic musical instrument processes, e.g. for improving processing capabilities or solving interfacing problems
• • G—PHYSICS
  • G10—MUSICAL INSTRUMENTS; ACOUSTICS
  • G10H—ELECTROPHONIC MUSICAL INSTRUMENTS; INSTRUMENTS IN WHICH THE TONES ARE GENERATED BY ELECTROMECHANICAL MEANS OR ELECTRONIC GENERATORS, OR IN WHICH THE TONES ARE SYNTHESISED FROM A DATA STORE
  • G10H2240/00—Data organisation or data communication aspects, specifically adapted for electrophonic musical tools or instruments
  • G10H2240/011—Files or data streams containing coded musical information, e.g. for transmission
  • G10H2240/046—File format, i.e. specific or non-standard musical file format used in or adapted for electrophonic musical instruments, e.g. in wavetables
  • G10H2240/056—MIDI or other note-oriented file format
• • G—PHYSICS
  • G10—MUSICAL INSTRUMENTS; ACOUSTICS
  • G10H—ELECTROPHONIC MUSICAL INSTRUMENTS; INSTRUMENTS IN WHICH THE TONES ARE GENERATED BY ELECTROMECHANICAL MEANS OR ELECTRONIC GENERATORS, OR IN WHICH THE TONES ARE SYNTHESISED FROM A DATA STORE
  • G10H2240/00—Data organisation or data communication aspects, specifically adapted for electrophonic musical tools or instruments
  • G10H2240/171—Transmission of musical instrument data, control or status information; Transmission, remote access or control of music data for electrophonic musical instruments
  • G10H2240/201—Physical layer or hardware aspects of transmission to or from an electrophonic musical instrument, e.g. voltage levels, bit streams, code words or symbols over a physical link connecting network nodes or instruments
  • G10H2240/241—Telephone transmission, i.e. using twisted pair telephone lines or any type of telephone network
  • G10H2240/251—Mobile telephone transmission, i.e. transmitting, accessing or controlling music data wirelessly via a wireless or mobile telephone receiver, analogue or digital, e.g. DECT, GSM, UMTS
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04M—TELEPHONIC COMMUNICATION
  • H04M19/00—Current supply arrangements for telephone systems
  • H04M19/02—Current supply arrangements for telephone systems providing ringing current or supervisory tones, e.g. dialling tone or busy tone
  • H04M19/04—Current supply arrangements for telephone systems providing ringing current or supervisory tones, e.g. dialling tone or busy tone the ringing-current being generated at the substations
  • H04M19/047—Vibrating means for incoming calls

Definitions

• the present invention relates to a tone reproduction device capable of changing tone colors, and a portable terminal device provided with the tone reproduction device.
• a tone reproduction device that generates a tone using hardware.
• Such a tone reproduction device is designed to be able to change the tone of the reproduced tone.
• FIG. 10 shows an example of the configuration of this musical sound reproducing apparatus, and the description for changing the timbre is given below.
• a CPU Central Processing Unit
• a CPU Central Processing Unit
• transmits sequence data such as MIDI (Musical Instrument Digital Interface) data and SMAF (Synthetic Music Mobile Application Format) data to a RAM (Random Access Memory) 1 1 1
• the sound source hardware section 115 reproduces the sequence data supplied from the RAM 111 and outputs a tone signal to the speaker 134.
• the sound source hardware section 115 includes a timbre parameter storage area 130 and a data processing section 133 for reproducing a tone.
• the timbre parameter storage area 130 is composed of areas and registers secured in the RAM 11.
• the CPU 110 when changing the tone of the tone to be reproduced, the CPU 110 gives a tone change command to the tone parameter storage area 130, and the CPU 110
• the timbre parameters of the timbre to be changed are read from AM I 11 and written to the timbre parameter storage area 130.
• the data processing unit 13 3 stores the timbre parameters of the timbre to be changed from the timbre parameter storage
• the read tone is reproduced by using the tone color parameter.
• the RAM I 11 can store many sequence data and a plurality of timbre parameters (timbre parameter group).
• the CPU 110 when changing the timbre, as described above, the CPU 110 reads out the timbre parameters of the timbre to be changed from the RAM 11 and transfers them to the sound source hardware unit 115.
• the data bus width of the tone generator hardware section 115 is about 8 bits
• the bit width of the RAM and the registers constituting the tone parameter storage area 130 is stored.
• the bit width of data is also limited to about 8 bits.
• the timbre parameters for one channel required when the data processing unit 133 reproduces and processes the sound of one channel are composed of many tens of bits.
• the data processing unit 1333 uses one 8-channel timbre parameter, which is required for the reproduction processing of one channel of sound, multiple times in units of 8 bits. Had to be read separately. As a result, it takes time to read out the timbre parameters of the timbre to be changed from the timbre parameter storage area 130 and set them in the data processing unit 133, which causes a problem that the processing time becomes longer.
• the timbre parameter storage area 130 is made up of dedicated registers, any number of registers can be read simultaneously, but the timbre parameter storage area 130 If the timbre parameter storage area 130 is shared with 8-bit wide general-purpose data other than the timbre parameters, the timbre parameter storage area 130 will be degraded as a memory. Problem arises.
• the timbre parameter storage area 130 is composed of a RAM having a large bit width, the timbre parameters with a large bit width can be read out at once, but the timbre parameter storage area 13 If 0 is dedicated to the timbre parameters, and the timbre parameter storage area 130 is shared with general-purpose 8-bit data other than the timbre parameters, the usage efficiency of the timbre parameter storage area 130 as a memory will deteriorate. Problem arises.
• the present invention provides a tone reproduction apparatus that stores tone parameters in general-purpose storage means so that time spent in tone change processing can be shortened, and a portable terminal including the tone reproduction apparatus. It is intended to provide a device. Disclosure of the invention
• a musical sound reproducing apparatus comprises: a general-purpose storage means capable of registering at least an arbitrary number of timbre parameter groups; a sound source means for reproducing a musical tone based on a timbre parameter; A cache memory having a large output data width for transferring parameters to the sound source means, and a timbre parameter of the timbre to be changed when the timbre to be set in the sound source means is changed is stored in the general-purpose storage means.
• the control means comprises system control means for performing a process other than the tone reproducing process as a main process.
• the timbre parameter of the timbre to be changed specified by the change command is read from the general-purpose storage means, transferred to the cache memory, and sent from the cache memory to the sound source means by the timbre change command specified by the timbre change command. Tone parameters may be transferred.
• the timbre change command may specify a timbre parameter of the timbre to be changed by specifying a head address of the timbre parameter in the general-purpose storage unit. .
• a portable terminal device of the present invention is a portable terminal device including the above-mentioned musical sound reproducing device, wherein the system control means executes portable terminal function processing as main processing. ing.
• system control means performs the timbre change processing by sending the head address of the timbre parameter to be changed in the general-purpose storage means, so that the amount of data transfer between the system control means and the tone reproduction device can be reduced.
• FIG. 1 is a diagram showing a configuration example of a mobile terminal device according to an embodiment of the present invention.
• FIG. 2 is a diagram showing a configuration example of a tone reproduction device mounted on the portable terminal device of FIG.
• FIG. 3 is a diagram showing a detailed configuration of a sound source memory, a control unit, and a cache memory in the sound source hard disk unit of FIG.
• Fig. 4 shows an example of the data structure of the tone parameter group registered in the tone generator RAM in Fig. 3.
• FIG. 4 shows an example of the data structure of the tone parameter group registered in the tone generator RAM in Fig. 3.
• FIG. 5 is a diagram showing an example of the data configuration of timbre parameters stored in the timbre cache memory in FIG.
• FIG. 6 is a flowchart of a reproduction process executed by the sound source hardware unit in FIG.
• FIG. 7 is a flowchart of the tone parameter memory registration process in step S2 in FIG.
• FIG. 8 is a flowchart of the tone color changing process in step S3 in FIG.
• FIG. 9 is a flowchart of the sound data processing in step S4 in FIG.
• FIG. 10 is a diagram showing a configuration example of a conventional musical sound reproducing device. BEST MODE FOR CARRYING OUT THE INVENTION
• FIG. 1 is a diagram illustrating a configuration example of a mobile terminal device according to an embodiment of the present invention.
• a mobile phone 1 as a mobile terminal device is generally provided with a retractable antenna 25 and can be connected to a base station 2 by a wireless line. 7
• the antenna 25 is connected to a communication unit 13 having a modulation / demodulation function.
• a central processing unit (CPU) 10 is a system control unit that controls the operation of each unit of the mobile phone 1 by executing a telephone function program, and indicates an elapsed time during the operation, or a specific operation.
• a timer (not shown) that generates a timer interrupt at time intervals is provided. Further, the CPU 10 transfers a predetermined amount of sequence data to the sound source hardware unit 15 at the time of reproducing a tone such as an incoming call.
• RAM I 1 is a RAM (Random Access Memory) in which a storage area for the sequence data downloaded from a down port or the like connected via the base station 2 and a queryer of the CPU 10 are set. ).
• the ROM 12 stores various types of transmission and reception telephone function programs executed by the CPU 10, programs for tone reproduction related processing, and various data such as preset sequence data. This is the ROM (Read Only Memory) stored.
• the communication unit 13 demodulates a signal received by the antenna 25, modulates a signal to be transmitted to the base station 2, and supplies the modulated signal to the antenna 25.
• the received signal demodulated by the communication unit 13 is decoded by a voice processing unit (coder / decoder) 14.
• the speech signal input from the microphone 21 is compression-coded in the voice processing unit 14.
• the audio processing unit 14 performs high-efficiency compression encoding / decoding of audio, and includes, for example, a coder / decoder of a CELP (Code Excited LPC) system or an AD PCM (adaptive differential PCM encoding) system.
• the sound source hardware unit 15 can output a reception melody and a hold tone by emitting a reception signal from the audio processing unit 14 from the reception speaker 22 or reproducing sequence data.
• the incoming melody is emitted from the incoming speaker 23, and the held tone is mixed with the receiving signal and emitted from the receiving speaker 22.
• the format of the sequence data is described as MIDI (Musical Instrument Digital Interface) format or SMAF (Synthetic Music Mobile Application Format) which is convenient for distribution.
• the sequence data in these formats is converted into the format control data unique to the sound source core incorporated in the sound source hardware unit 15 and reproduced.
• the CPU 10 converts the sequence data into control data in a format unique to the sound source hardware unit 15 and stores it in the RAM 11, and reads out from the RAM 11 during playback to read out the sound source hardware unit 1. 5 may be supplied.
• the sound source hardware section 15 is provided with a general-purpose RAM for registering an arbitrary number of tone parameter groups, a cache memory having a large output bit width, and a sound source core.
• the tone parameter group registered in the general-purpose RAM is, for example, a tone parameter group of the GM sound source standard.
• the timbre parameters of the tone specified for each channel are stored in the cache memory, and the tone generator core performs one or several accesses from the cache memory once or several times to reproduce the tone on that channel.
• the timbre parameters can be read out.
• the interface (IZF) 16 is used for external devices such as personal computers.
• the input unit 17 is an input means including dial buttons “0” to “9” and various buttons provided on the mobile phone 1.
• the display unit 18 is a display unit that displays a menu corresponding to a telephone function and a display corresponding to an operation of a button such as a dial button.
• the vibrator 19 is a vibrator that notifies the user of an incoming call by vibrating the main body of the mobile phone 1 instead of a ring tone at the time of an incoming call.
• Each functional block exchanges data and the like via the bus 24.
• FIG. 2 shows an example of the configuration of a tone reproduction device mounted on the portable terminal device of FIG.
• the receiving speaker 22, the receiving speaker 23 and the speaker 34 are omitted from the configuration.
• the CPU 10, the sound source hardware unit 15, and the RAM 11 in the figure exchange data via the bus 24.
• RAMI 1 stores sequence data and a group of tone parameters of various tones according to the GM tone generator standard and the like.
• a tone parameter group stored in the RAMI 1, for example, in accordance with the GM tone generator standard is transferred to and registered in the tone generator memory 30 of the tone generator hardware unit 15 under the control of the CPU 10.
• the CPU 10 gives the timbre parameter transmission instruction a to the RAMI 1 to sequentially read the timbre parameters in the timbre parameter group to be registered, and reads out the read timbre parameter b.
• the CFU 10 gives the timbre parameter write command (register timbre parameters to the memory) c to the control unit 31.
• the control unit 31 stores the timbre parameter b in the sound source memory.
• An address to be written to 30 is generated, and a tone parameter writing instruction d is given to the tone generator memory 30.
• the timbre parameter a read from the RAMI 1 is written to a predetermined area of the tone generator memory 30.
• the timbre parameter table in which the head address of each timbre parameter registered in the tone generator memory 30 is written is stored by the CPU 10 in the work area of the RAMI 1.
• the CPU 10 gives the timbre change command c to the control unit 31.
• the control unit 31 having received the tone color change instruction c gives the tone color parameter transmission instruction d for transmitting the designated tone color parameter to the cache memory 32 to the sound source memory 30.
• the tone generator memory 30 reads out the specified tone color parameter, and transmits the read tone color parameter e to the cache memory 32. Then, although not shown, the tone generator core 33 converts the sequence data supplied from the control unit 31 into control data in a format specific to the tone generator core 33 during the reproduction of the musical sound, and generates each event in the control data. When the reproduction timing has been reached, a tone parameter read request h is given to the cache memory 32. The cache memory 32 receiving this reads out the timbre parameter g and sends it to the tone generator core 33.
• the output bit width of the cache memory 32 is set to, for example, a bit width capable of sending a tone parameter g for one channel at a time, and immediately sets the tone parameters to the tone generator core 33. can do.
• the sound source core 33 reproduces the tone of the changed tone using the changed tone parameter, sends the reproduced data i to the speaker 34, and emits the tone.
• FIG. 3 is a diagram showing a detailed configuration of the sound source memory 30, the control unit 31, and the cache memory 32 in the sound source hardware unit 15 of FIG. 2.
• FIG. 4 is a diagram showing the sound source RAM 30 in FIG.
• FIG. 5 is a diagram showing a data configuration example of a tone color parameter group registered in a
• FIG. 5 is a diagram showing a data configuration example of a tone color parameter stored in a tone color cache memory 32a in FIG.
• the tone parameter write instruction c from the CPU 10 is given to the tone generator memory address generation circuit 31a, an address for writing the registered tone parameters is generated, and the address of the tone generator RAM 30a is generated. It is given to the input terminal.
• the sound source RAM 30a is a general-purpose memory having an input bit width and an output bit width of, for example, 8 bits.
• the timbre parameter b is sequentially written to the address position sequentially given from the tone generator memory address generation circuit 31a.
• an arbitrary number of tone color parameter groups for example, all tone color parameters conforming to the GM tone generator standard can be written to the tone source RAM 30a.
• the starting address for writing each tone parameter to the tone generator RAM 30a is given to the tone generator memory address generation circuit 31a by the CPU 10 as a part of the tone parameter write instruction c, and the initial address of each tone parameter is given. Is stored in: AMI 1.
• the data configuration of the tone color parameter group registered in the tone generator RAM 30a is, for example, as shown in FIG. That is, the bit width of the tone generator RAM 30a is set to 8 bits, and the tone parameter 1 is stored in the address "1000h (h indicates a hexadecimal number)" to the address "100Fh", and the address "1 100h” ⁇ Tone parameter 2 is stored in address "1 10 Fh”, and timbre parameter 3 is stored in address "2 FF 0 h" to address "2 FFFh”.
• Each tone parameter is stored, for example, in an area of 16 rows x 8 bits where addresses are continuous, so that each time the incremented address is given from the tone generator memory address generation circuit 31a, the tone parameter is divided into a maximum of 8 bits.
• the separated tone parameters are written into the tone source RAM 30a.
• one timbre parameter is divided into fragments of 8 bits or less, divided into 16 fragments, and registered in the sound source RAM30a.
• the timbre parameters registered in the sound source RAM 30a are a timbre parameter group including timbre parameters 1 to m (m is an arbitrary integer).
• the tone parameters shown in Fig. 4 are tone parameters for FM sound sources. These tone parameters are SR (sustain rate), ERB (repurb on Z off), SUS (sustain level), RR (release rate), DR (decay rate), ..., WS (waveform selection), FB (Feedback level).
• a predetermined tone color parameter group is stored in the sound source ROM 30b in advance, and its data configuration is the same as the data configuration example shown in FIG.
• the timbre change instruction c output from the CPU 10 when changing the timbre is applied to the register address generation circuit 31b.
• the timbre parameter of the timbre to be changed by the timbre change instruction c is specified by omitting the head address of the sound source RAM 30a and its channel number. Therefore, the register address generation circuit 31b rewrites the voice address of the corresponding channel of the voice address register in the control register 31c from the head address and the channel number of the timbre parameter specified by the timbre change instruction c.
• This voice address register consists of registers for the maximum number of simultaneous sounding channels (slots), and the head address of the tone parameter set for each slot is written as a voice address in the register of each slot (channel). Then, the Voice Adr (voice address) change detection circuit 31d detects which channel the voice address has been changed to, and the cache transfer wait queue register 3 1 detects the slot number corresponding to the channel whose voice address has been changed. Send to e.
• the cache transfer waiting queue register 31 e is a register for creating a queue of slot numbers for sequentially transferring tone parameters when tone change is performed over a plurality of channels at one time. In First Out).
• the first slot number output from the cache transfer wait queue register 31 e is given to a slot number (slot number) Voice Adr conversion circuit 31 f, and the voice address register in the control register 31 c is controlled by the circuit. Is referenced, and the slot number is converted to the voice address written in the register of the corresponding slot. As described above, this voice address is the head address of the tone parameter specified for the corresponding channel, and the tone parameter transmission instruction d including the head address from the Slot No-Voice Adr conversion circuit 31 f is the sound source d. It is provided to the memory address generation circuit 31a.
• the head address included in the tone parameter transmission instruction d is within the address range of the sound source RAM 30a or the address range of the sound source R0M30b.
• the specified tone color parameter is read from the tone generator RAM 30a or the tone generator ROM 30b whose start address is within the address range. This place In this case, the tone generator memory address generation circuit 31a increments, for example, the head address by 15 times and reads out all the tone parameters for one channel.
• the read and specified tone color parameter e is supplied to the data input terminal of the tone color cache memory 32a via the selector 30c.
• the head slot number output from the cache transfer wait queue register 31e is also given to the cache address generation circuit 32b as a tone parameter reception instruction f.
• the timbre cache memory 32a can store timbre parameters for the maximum number of simultaneous tone generation channels, and the cache address generation circuit 32b generates a cache address corresponding to a given slot number. Give it to the address input terminal of the tone cache memory 32a. As a result, the tone parameter set in the tone cache memory 32 a at the slot number designated by the cache address can be rewritten by the designated tone parameter e sent from the selector 30 c. .
• the sequence data is supplied to the control register 31c, is converted into a format specific to the sound source core 33, and when the playback timing of each event in the control data comes, the control register 31c transmits the sequence data to the control register 31c. 3 will be set to 3.
• the tone generator core 33 reproduces the musical tone based on the sequence data.
• the tone parameters set for each channel reproduced by the tone generator core 33 are read from the tone cache memory 32a. I will get it. That is, when the playback timing of each event comes, the tone generator core 33 gives the slot number corresponding to the channel to be played back as the timbre parameter read request h to the cache address generation circuit 32b.
• the cache address generation circuit 32b receiving this generates a cache address of the position where the tone color parameter set in the slot number is stored, and gives it to the tone color cache memory 32a.
• the tone parameter set for the slot number is sent to the tone generator core 33 at one time, for example, and the tone source core 33 corresponds to the slot number using the sent tone parameter. Play the music of the channel you want to play.
• the data structure of the timbre parameters stored in the timbre cache memory 32a Fig. 5 shows an example.
• the output bit width of the tone cache memory 32a is several tens of bits that can store tone parameters for one channel, consisting of ⁇ , ⁇ Width.
• the tone cache memory 3 2 a has the same number of lines as the maximum number of simultaneous sounds of the tone generator core 33. That is, the first line (# 0) stores the timbre parameters of channel 1, the second line (# 1) stores the timbre parameters of channel 2, and similarly the Nth line
• the eye (#N) stores the timbre parameters for channel N. Note that N is the maximum polyphony equal to one.
• the timbre cache memory 32a has a wide output bit width (for example, about 60-bit width)
• the timbre parameters for one channel can be stored in the sound source core 33 at a time. Can be sent to As a result, the timbre parameters can be instantaneously transmitted to the tone generator core 33, and the tone can be reproduced without interruption.
• the processing of the corresponding key-on event is temporarily suspended (key-on mask) until the transfer of the specified tone parameters to the tone cache memory 32a is completed, and the tone parameter is changed.
• the information of the slot number corresponding to the channel whose timbre output from the Voice Adr change detection circuit 31 d is changed is given to the key-on mask circuit 31 g.
• the key-on mask circuit 31g generates a key-on mask signal for masking the key-on of the channel corresponding to the given slot number information and sends it to the tone generator core 33.
• the key-on in that channel is masked, and the reproduction of the musical sound is temporarily stopped.
• the transfer completion flag is raised, and the key-on mask circuit 31g is reset to the original state.
• the rewritten timbre parameter newly set to the slot number is sent to the tone generator core 33, and the tone generator core 33 uses the sent timbre parameter to reproduce the tone-changed tone of the channel. It will be able to be played reliably.
• the sound source core 33 When the sound source core 33 is composed of a PCM sound source, various sampling waveforms can be stored in the sound source ROM 30b and the sound source RAM 30a. And At the time of musical tone reproduction, a waveform address of the designated timbre is given from the sound source core 33 to the sound source memory address generation circuit 31a.
• the sound source memory address generation circuit 31a determines whether the given waveform address is within the address range of the sound source RAM 30a or the address range of the sound source ROM 30b, and determines the waveform address force.
• the specified waveform data is read from the sound source RAM 30a or the sound source ROM 30b within the range.
• the read waveform data is supplied to the tone generator core 33 via the selector 30c, and the tone generator core 33 reproduces a musical tone of the designated timbre using the waveform data.
• the sound source RAM 30a is a general-purpose memory that can store not only timbre parameters but also other data.
• FIG. 6 shows a flowchart of the reproduction processing executed by the sound source hardware section 15 in FIG.
• step S1 initialization processing for initializing the sound source hardware unit 15, such as resetting various registers or setting default values, is performed.
• step S2 the memory registration processing of the tone color parameters in step S2, the tone color change processing in step S3, and the tone data processing in step S4 are performed in parallel.
• steps S2 to S4 are repeatedly executed until the end of the sequence data or the stop instruction is issued, whereby the reproduced musical tone based on the sequence data is output.
• FIG. 7 shows a flowchart of the process of registering the timbre parameters in the memory of step S2 in FIG.
• step S10 of FIG. 7 CPU 10 starts It is determined whether there is a registration request.
• the given to the tone color parameter Rye preparative instruction Ji Ka? Tone Hadouwea unit 1 5 from CPU 1 0 if the tone color parameter transmitting command a has been given to the R AM I 1, the determination is YES
• the process proceeds to step S 11, and the timbre parameters read from the RAM I 1 in step S 11 are registered in the sound source RAM 30 a in the sound source memory 30.
• the memory registration process of the tone parameters is completed, and the process returns after step S1. If it is determined in step S 10 that there is no registration request from the CPU 10, the memory registration processing of the timbre parameter is terminated and the routine is returned.
• FIG. 8 shows a flowchart of the tone color changing process in step S3 in FIG.
• the tone color change process is started by a tone color change message or the like embedded in the sequence data. It is determined whether the CPU 10 has issued a tone change command.
• the CPU 10 has given the timbre change command c to the control unit 31 in the sound source hardware unit 15, it is determined to be YES, and the process proceeds to step S 21 and step S 22.
• step S21 the designated timbre parameters are read from the tone generator RAM 30a or the tone generator ROM 30b and transmitted to the tone cache memory 32a.
• step S22 which is processed in parallel with step S21, the transmitted timbre parameters are received in timbre cache memory 32a, and the timbre parameters of the designated channel are rewritten.
• step S21 and step S22 When the processing of step S21 and step S22 is completed, the tone change processing ends and the process returns to step S1. Also, in step S20, when it is determined that the timbre change command from CPU 10 has not been received, the timbre change process is terminated and the routine is returned.
• FIG. 9 shows a flowchart of the sound data processing in step S4 in FIG.
• step S30 it is determined whether or not key-on has been set in sound source core 33 and key-on is being performed.
• the tone generator core 33 reads the tone parameter of the channel to be reproduced from the tone cache memory 32a.
• data processing for reproducing a musical tone is performed based on the timbre parameters read in step S32 and the control data set in the tone generator core.
• step S33 the tone data reproduced in step S33 is output (produced).
• the sound data processing ends and the flow returns to step S1.
• the sound data is also processed.
• the timbre parameters for one channel are sent to the tone generator core 33 in one access from the timbre cache memory 32a, but the output bit width is slightly reduced. Then, the tone parameters for one channel may be sent to the sound source core 33 in several accesses. Even in this case, there is almost no effect of sound interruption due to the processing time.
• the musical sound reproducing device of the present invention described above is not applied only to the above-described portable telephone 1 which is a portable terminal device, but includes a portable information device capable of outputting a musical sound, a portable personal computer capable of outputting a musical sound, and the like. Can be applied to At this time, the music content data may be reproduced in synchronization with the text or image content.
• the sound source core 33 in the sound source hardware unit 15 can be constituted by a frequency modulation type sound source, that is, an FM sound source.
• FM sound sources use harmonics generated by frequency modulation to synthesize musical tones, and can generate waveforms with harmonic components including non-harmonic sounds with a relatively simple circuit.
• FM sound sources can generate a wide range of musical sounds, from synthetic sounds of natural instruments to electronic sounds.
• the FM sound source uses an oscillator called an operator that oscillates a sine wave equivalently.
• an FM sound source can be configured by cascading a first operator and a second operator.
• An FM sound source can also be configured by inputting the output of the operator by feedback.
• the sound source method of the sound source core 33 in the sound source hardware unit 15 is not limited to the FM sound source method, but may be a waveform memory sound source (PCM sound source, ADPCM sound source) method, a physical model sound source method, or the like.
• the configuration of the sound source may be a hardware sound source using a DSP or the like.
• general-purpose storage means capable of registering an arbitrary number of tone parameter groups, and a cache memory having a large output data width are provided. Therefore, when changing the timbre, the timbre parameter designated for change read from the general-purpose storage means may be transferred to the cache memory.
• the timbre parameters since an arbitrary number of timbre parameter groups are registered in the general-purpose storage means, it is possible to minimize the need to transfer the timbre parameters from the system control unit to the general-purpose storage means every time the timbre is changed. Can be.
• the output bit width of the cache memory is increased, the timbre parameters can be set to the tone generator instantaneously. As described above, even if the timbre parameters are stored in the general-purpose storage means, the time spent in the timbre change processing can be reduced, and the occurrence of a tone cut when changing the timbre can be prevented.
• the system control means performs the timbre change processing by sending the head address of the timbre parameter to be changed in the general-purpose storage means, so that the data between the system control means and the tone reproduction apparatus is The transfer amount can be reduced.

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• General Engineering & Computer Science (AREA)
• Electrophonic Musical Instruments (AREA)
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• Memory System Of A Hierarchy Structure (AREA)
• Mobile Radio Communication Systems (AREA)

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