JPH0448399B2 - - Google Patents

Description

[Detailed Description of the Invention] "Industrial Application Field" This invention can be used, for example, to multiplex text signals or musical score information onto a television signal, and to display the text information or play music on the receiver side. The present invention relates to a musical tone information receiving device for multiplexed broadcasting that can generate and transmit information.

``Prior Art'' The conventional method of transmitting musical tone information is to convert musical tone information into a digital signal in real time using an A/D converter, transmit this digital signal to a remote location by wire or wirelessly, and then transmit the digital signal to a remote location by wire or wirelessly. A common method is to convert it back into an analog signal and reproduce the original musical tone information.
Another recording method is to convert musical tone information into a digital signal using an A/D converter, record this digital signal on a storage medium, and then read it out and decode it into an analog signal to reproduce musical tone information. It is taken.

Whichever method you use, conventionally the musical tone signal is sent as is.
Since it is converted into a digital signal through AD conversion and then transmitted or recorded on a storage medium, the time required for transmission or storage is exactly the same as the length of analog information. .

As a result, there is a disadvantage that information cannot be transmitted in a time shorter than the time of actual analog information.

Furthermore, according to the conventional method, if noise is mixed in the transmission path or the reading system from the storage medium,
The influence of the noise has the disadvantage of directly deteriorating the sound quality.

In particular, in the case of musical tone information, since the method involves AD converting, transmitting, or storing information including all information from high to low tones, the amount of information contained at each instant is relatively large. As a result, there are disadvantages in that it takes time for transmission and that the occupied band required for transmission is relatively wide. Furthermore, when recording on a storage medium, the number of bits of the digital signal becomes large, so there is an inconvenience that the capacity of the storage medium is also required.

In order to eliminate such inconveniences, new musical tone information transmission systems are being considered. Unlike the method of A/D converting sounds, this musical sound information transmission method converts the musical score for playing music into digital codes,
This is a method in which this musical score information is divided into parts and transmitted.

In other words, when using a wireless transmission method, as shown in FIG.
1 will be provided. This music score symbol conversion device 101 is the fifth
As shown in the figure, this is a device that converts each symbol 601, 602, 603, 604...612 of a musical score for playing music into a predetermined digital code. In the musical score symbol conversion device 101, the order of conversion into digital symbols is performed for each part. In other words, staff A shown in Figure 5 is the treble part, staff B
is the bass part. Generally, the treble part shown on staff A is for example piano, guitar, violin, etc.
A melody is played by a pitched instrument such as a flute or clarinet. Furthermore, the bass part shown on staff B is played with a rhythm, or generally an accompaniment, by an unpitched instrument such as a top cymbal, high hat, or drum. This example shows two parts, but in reality, depending on the song to be played, the number of staves corresponding to the number of instruments used in that song or the number of chorus parts is prepared, and the notes on each staff are The symbols 601, 602, 603, . . . are converted into digital codes in order from the beginning. In other words, once all staves A have been converted into digital codes, staff B is then converted into digital codes from the beginning, and this is repeated for the number of parts. The order of transmission is from the part with the highest priority. Generally, the melody part is sent first, and once all of the melody part has been sent, the accompaniment part is sent.

FIG. 6 shows an example of musical score information. The meaning of each symbol in the score information is as follows.

SOT: Identification code that indicates the beginning of the song, DLG: Identification code that indicates the byte length of the song data, TMP: Identification code that specifies the tempo of the song, ST1 to ST12: Note information for each part, INS: Specification of instrument sound , EOC: End of part, EOT: Identification code indicating end of song. The musical score symbol conversion device 101 shown in FIG. Convert to digital signal. The digital signals outputted from this musical score symbol conversion device 101 are made into parallel 8-bit signals, for example, and are stored in a memory 102. Memory 102
The musical score information stored in is read out as necessary, converted into a serial signal by a parallel-to-serial converter 103, and further added with an error correction code by an error correction code addition circuit 104 as necessary, and sent to a wireless transmission means 105. For example, the signal is inserted into the vertical retrace period of the television signal and transmitted from the antenna 106 on radio waves.

In the receiving device 200, an antenna 201 receives a radio wave with musical score information, a demodulation circuit 202 demodulates it, an error correction circuit 203 performs error correction processing,
It is imported into the main storage device 205 via the microcomputer 204. In this case, the signals written from the microcomputer 204 to the main storage device 205 are converted into parallel signals and then written.

As shown in FIG. 7, the main storage device 205 has, for example, 24 storage areas M ₁ , M ₂ , M ₃ , M ₄ . . . for each part.
... M ₂₄ is provided, and the musical score information sent from the transmitting side 100 is stored in storage areas M ₁ , M 2 , and M ₂ for each part.
M ₃ , M ₄ ... are stored in M ₂₄ .

The musical score information taken into the main storage device 205 is sequentially read out in parallel for each part by the microcomputer 204 from the first address. In _other words, _the first address of each storage area M ₁ , _{M 2} , M ₃ , M ₄ . It is read out for each storage area. In this way, the information for each part is read out in a time-division manner and sent to tone generation circuits 206A-206P assigned to each part. Two types of musical tone generation circuits 206A to 206P are prepared: one for pitched instruments and one for unpitched instruments.

The musical sound generation circuits 206A to 206P each receive the musical score information of each part, decode the musical score information, and convert it into a musical sound signal having the tone of each part.

In this way, each musical tone signal conversion circuit 206A~
A musical tone signal is output from 206P according to the musical score information. For example, as shown in FIG. 8, this musical tone signal is output in the form of a pulse modulation signal with a duty ratio of 1/the number of parts, so it is smoothed by a filter 207, converted to a low frequency signal, and then sent to a low frequency amplifier. The signal is amplified at 208 and emitted as sound from a speaker 209 .

By transmitting musical score information and converting it into a musical tone signal in this manner, the time required to transmit musical score information can be much shorter than the actual performance time of the song. Therefore, a large amount of musical tone information can be transmitted in a short period of time. Furthermore, when the songs are stored in a storage medium, there is an advantage that a large number of songs can be stored in a memory with a small capacity.

"Problems to be Solved by the Invention" The main memory provided in the receiving device 200 has a limited capacity. In other words, musical tone signal generation circuit 2
The number of parts that can be reproduced is determined according to the number of parts 06A to 206P. As a result, the main storage device 205 is determined to have a capacity that accommodates the number of parts corresponding to the number of musical tone signal generation circuits 206A to 206P.

Two standards are being considered as proposals for this type of multiplexed broadcasting. The first standard is a standard that can send pitched instrument information up to 6 and unpitched instrument information up to 5, and the second standard is information on pitched instruments.
16. A standard is being considered that can transmit up to 8 pieces of information about unpitched instruments.

When these two broadcasting standards are used together, if the information of the second standard is input into a receiver made for the first standard, the main memory stores 11 parts of the information of the pitched instrument that is sent first. Then the main storage device 20
5 becomes full and becomes unable to take in the information of unpitched instruments.

As a result, a performance consisting only of the melody and no accompaniment is played back.

"Means for Solving the Problems" This invention provides a musical tone information receiver made for the first standard including means for counting the number of pitched instrument information to be loaded into the main storage device, and a method for counting the number of pitched instrument information to be loaded into the main memory. When the number reaches a predetermined value, for example, when 6 parts are stored, there is a means for prohibiting the import of pitched instrument information from then on, and a means for canceling the prohibition when unpitched instrument information is input in this prohibited state. The apparatus is provided with means for importing unpitched musical instrument information into a storage device.

With this configuration, it is possible to take in the minimum necessary information for the melody section and the minimum necessary information for the accompaniment section, so that even musical tone information receiving devices made for the first standard can receive musical tones for the second standard. Information can be received and reproduced in almost normal condition.

"Embodiment" FIG. 1 shows an embodiment of the present invention. FIG. 1 shows a receiving device 200. As shown in FIG. Radio waves received by the receiving antenna 201 are demodulated by the demodulation circuit 202, subjected to error correction processing by the error correction circuit 203, and then taken into the microcomputer 204.

The microcomputer 204 determines whether the received musical score information is musical score information of a pitched instrument or musical score information of an unpitched instrument. This determination is made based on the instrument sound designation code INS included in the music score information.

In this invention, there is provided a means for counting the number of input pitched instrument information, and a means for counting the number of input pitched instrument information, and a main storage device 2
5 includes means for prohibiting writing of pitched instrument information, and when unpitched instrument information is input in this prohibited state, the prohibition is canceled and the unpitched instrument information is stored in the main storage device 2.
05.

In a receiver made for the first standard, the main storage device 205 has a storage area of M 1 to M ₁ as shown in FIG.
11 areas of M ₁₁ are prepared. For this reason, in the receiver for the first standard, when the pitched musical instrument information for six parts is taken into the main storage device 205, writing of the pitched musical instrument information is prohibited in that state. The write inhibiting means, the pitched musical instrument information counting means, and the unpitched musical instrument information writing means are constituted by a program stored in the microcomputer 204.

Figure 3 shows an outline of the program.

It is determined whether the musical score information input in step is pitched musical instrument information.

If it is pitched instrument information, proceed to step. In the step, it is determined whether or not the number of musical score information written in the main storage device 205 is 6 or less. If the number of pitched musical instrument information written to the main storage device 205 is 6 or less, the musical instrument information is written to the main storage device 205 in step.

In the step, it is determined whether the main storage device 205 is full or not, and if it is not full, the process returns to the step.

If it is determined in step that the number of pitched musical instrument information written in the main storage device 205 is six or more, the process branches to step and writing of pitched musical instrument information is prohibited.

In the prohibited state, a routine consisting of steps is repeatedly executed. When unpitched musical instrument information is input in the prohibited state, the process branches from step to step, cancels the write prohibition, and writes the unpitched musical instrument information to the main storage device 205.

After executing the step, it is determined in the step whether the main memory 205 is full or not, and if it is not full, the process returns to the step and the process continues.
This routine is executed to write the unpitched instrument information to the remaining storage area of the main storage device 205.

When six parts of pitched instrument information and five parts of unpitched instrument information are loaded into the main storage device 205 in this manner, the execution of the program ends and the reception is completed.

After the reception is completed, the microcomputer 204 reads the musical score information of each part from the main memory 205 from the first address by giving a reproduction command as necessary, and transfers this musical score information to the musical sound generation circuit. In the example of FIG. 1, the musical tone signal generators for pitched instruments 206X and the musical tone signal generators for unpitched instruments 206Y are collectively shown. These musical tone signal generation groups 206X and 206Y convert the respective musical instrument information into musical tone signals,
The signals are mixed and smoothed, converted into a low frequency signal, and supplied to an amplifier 208, which is then reproduced as sound from a speaker 209.

"Operations and Effects of the Invention" As described above, according to the present invention, it is possible to use a receiver for the first standard, which can receive a small number of musical instruments, and to receive musical instrument information of a number greater than the number of musical instruments of the first standard. If there are receivers for the second standard, even if the signal for the second standard is given to the receiver for the first standard, the minimum necessary information on the melody part and accompaniment part can be taken in.

Therefore, even if a receiver for the first standard receives a signal of the second standard, a substantially normal performance can be reproduced. Therefore, both the receiver for the first standard and the receiver for the second standard can share and receive the same information, and the effect is very great in practical use.

[Brief explanation of drawings]

FIG. 1 is a block diagram for explaining an embodiment of the present invention, FIG. 2 is a diagram for explaining the internal structure of a main storage device used in this invention, and FIG. 3 is an operation of the main part of this invention. 4 is a block diagram for explaining the conventional technology, FIG. 5 is a diagram for explaining an example of musical score,
Fig. 6 is a diagram for explaining the arrangement of musical score data, Fig. 7 is a diagram for explaining the internal structure of the main memory used in the conventional technology, and Fig. 8 is a diagram for explaining the signal output from the musical tone signal generation circuit. It is a waveform diagram for explanation. 100...Transmission device, 101...Music symbol conversion device, 102...Memory, 103...Parallel-serial converter, 104...Error correction code addition circuit, 10
5... Transmitting device, 106... Transmitting antenna, 20
1... Receiving antenna, 202... Demodulation circuit, 20
3...Error correction circuit, 204...Microcomputer, 205...Main storage device, 206A-20
6K...music signal conversion circuit, 207...low pass filter, 208...low frequency amplifier, 209...
speaker.

Claims (1)

[Scope of Claims] A. Musical score information for each part for playing a plurality of pitched instruments and a plurality of unpitched instruments is digitally encoded and transmitted, and a main unit that takes in this digitally encoded musical score information. A storage device; B. A means for counting the number of parts of a pitched musical instrument to be loaded into the main storage device; and C. When the number of parts of a pitched musical instrument to be loaded into the main storage device reaches a preset number. (D) means for prohibiting the retrieval of information on pitched instruments from then on; D means for importing information on unpitched instruments into the main storage device when information on unpitched instruments is sent in this prohibited state; A musical tone information receiving device consisting of.