Recording and reproducing methods and recording and reproducing apparatus

What we claim is:

1. In a recording method comprising the steps of converting an original sound signal into a digital sound signal in a selected conversion range, selecting said conversion range in accordance with amplitude information of said original sound signal, and storing and recording said digital sound signal,

the improvement wherein a width A of said conversion range is:

where:

A0 is a width of a maximum conversion range,

i is a variable integer and,

k is a fixed integer and,

j is a variable integer and,

and selecting means for determining i and j in accordance with said amplitude information.

2. A recording method according to claim 1, wherein said step of converting comprises forming said digital sound signal to have a constant number of bits.

3. In a recording apparatus comprising:

a first selecting means for selecting a conversion range which corresponds to amplitude information of an original sound signal;

a first converting means for converting said original sound signal into a digital sound signal in the conversion range selected by said first selecting means; and

a first memory means for storing said digital sound signal converted by said first converting means,

the improvement wherein a width A of said conversion range is:

where:

A0 is a width of a maximum conversion range,

i is a variable integer and,

k is a fixed integer and,

j is a variable integer and,

and comprising means for determining i and j in accordance with said amplitude information.

4. A recording apparatus according to claim 3, wherein said digital sound signal has a constant number of bits.

5. A recording apparatus according to claim 3, wherein said first selecting means comprises:

a first amplitude level detecting means for detecting the amplitude level which corresponds to said amplitude information of said original sound signal; and

a first conversion range selecting means for selecting a conversion range on the basis of the information on said amplitude level detected by said first amplitude level detecting means.

6. A recording apparatus according to claim 3, wherein said first memory means stores the information on said conversion range selected by said first selecting means as well as said digital sound signal.

7. A recording apparatus according to claim 3, wherein said first converting means comprises:

a first A/D converting means for converting said original sound signal from the analog signal into a digital signal; and

a signal compressing means for converting the A/D conversion signal obtained by said first A/D converting means into a compression signal of a smaller number of its than the number of bits of said A/D conversion signal in the conversion range selected by said first selecting means so as to obtain said digital sound signal.

8. A recording apparatus according to claim 3, wherein said first converting means comprises:

a second A/D converting means for converting said original sound signal from the analog signal into a digital signal; and

an A/D conversion range changing means for changing the maximum inputting range of said second A/D converting means in correspondence with the conversion range selected by said first selecting means.

9. A recording apparatus according to claim 8, wherein said first converting means comprises:

a variable inputting means for generating a signal by amplifying and/or attenuating said original sound signal;

third A/D converting means or converting said signal obtained from said variable inputting means from the analog signal into a digital signal; and

a first gain changing means for changing the gain of said variable inputting means in correspondence with the conversion range selected by said first selecting means.

10. In a reproducing method comprising the steps of reading a recorded digital sound signal, converting said digital sound signal into an analog sound signal in a selected conversion range, selecting said range in correspondence with amplitude information of said digital sound signal, and reproducing said analog sound signal,

the improvement wherein a width A of said conversion range is:

where:

A0 is a width of a maximum conversion range,

i is a variable integer and,

k is a fixed integer and,

j is a variable integer and,

and selecting means for determining i and j in accordance with said amplitude information.

11. A reproducing method according to claim 10, wherein said digital sound signal has a constant number of bits.

12. In a reproducing apparatus comprising:

a memory means for storing a digital sound signal;

a selecting means for selecting a conversion range which corresponds to the amplitude information of said digital sound signal; and

a converting means for converting said digital sound signal into an analog sound signal in said conversion range selected by said selecting means,

the improvement wherein a width A of said conversion range is:

where:

A0 is a width of a maximum conversion range,

i is a variable integer and,

k is a fixed integer and,

j is a variable integer and,

and comprising means for determining i and j in accordance with said amplitude information.

13. A reproducing apparatus according to claim 12, wherein said digital sound signal has a constant number of bits.

14. A reproducing apparatus according to claim 12, wherein said selecting means comprises:

an amplitude level detecting means for detecting the amplitude level which corresponds to said amplitude information of said digital sound signal; and

a conversion range selecting means for selecting a conversion range on the basis of the information on said amplitude level detected by said amplitude level detecting means.

15. A reproducing apparatus according to claim 12, wherein said memory means is coupled to store information on said conversion range selected by said selecting means as well as said digital sound signal.

16. A reproducing apparatus according to claim 12, wherein said converting means comprises:

a signal expanding means for expanding said digital sound signal into an expansion signal of a larger number of bits than the number of bits of said digital sound signal in the conversion range selected by said selecting means; and

a D/A converting means for converting said expansion signal obtained by said signal expanding means from the digital signal into an analog signal.

17. A reproducing apparatus according to claim 12, wherein said converting means comprises:

a second D/A converting means for converting said digital sound signal from the digital signal into an analog signal; and

a D/A conversion range changing means for changing the maximum outputting range of said second D/A converting means in correspondence with the conversion range selected by said selecting means.

18. A reproducing apparatus according to claim 12, wherein said converting means comprises:

a second D/A converting means for converting said digital sound signal from the digital signal into an analog signal;

a variable outputting means for amplifying and/or attenuating the signal obtained by said second D/A converting means; and

a gain changing means for changing the gain of said variable outputting means in correspondence with the conversion range selected by said selecting means.

19. In a recording apparatus having a first amplitude level detecting means for detecting an amplitude level which corresponds to amplitude information of an original sound signal and outputting a digital amplitude signal which corresponds to the original sound signal; a first conversion range selecting means for selecting a conversion range on a basis of the digital amplitude signal; a first converting means for converting the original sound signal into a digital sound signal in the conversion range selected by the first conversion range selecting means; and a first memory means for storing the digital sound signal converted by the first converting means;

the improvement wherein said first conversion range selecting means comprises a comparator for generating a range over signal when a value of the digital amplitude signal is larger than a maximum value in the conversion range currently selected; and a conversion range specifying circuit for enlarging the conversion range by one stage when a count value of the range over signal generated within a fixed period is greater than a predetermined value.

20. A recording apparatus having a first amplitude level detecting means for detecting an amplitude level which corresponds to amplitude information of an original sound signal and outputting a digital amplitude signal which corresponds to the original sound signal; a first conversion range selecting means for selecting a conversion range on a basis of the digital amplitude signal; a first converting means for converting the original sound signal into a digital sound signal in the conversion range selected by the first conversion range selecting means; and a first memory means for storing the digital sound signal converted by the first converting means;

the improvement wherein said first conversion range selecting means comprises a comparator for generating a range over signal when a value of the digital amplitude signal is larger than a maximum value in the conversion range one stage narrower than the conversion range currently selected; a conversion range specifying circuit for narrowing the conversion range by one stage when a count value of the range over signal generated with a fixed period is smaller than a predetermined value.

21. In a recording apparatus having a first amplitude level detecting means for detecting an amplitude level which corresponds to amplitude information of an original sound signal and outputting a digital amplitude signal which corresponds to the original sound signal; a first conversion range selecting means for selecting a conversion range on a basis of the digital amplitude signal; a first converting means for converting the original sound signal into a digital sound signal in the conversion range selected by the first conversion range selecting means; and a first memory means for storing the digital sound signal converted by the first converting means;

the improvement wherein said first conversion range selecting means comprises a comparator for generating a first range over signal when a value of the digital amplitude signal is larger than a maximum value in the conversion range currently selected and generating a second range over signal when the value of the digital amplitude signal is larger than the maximum value in the conversion range one stage narrower than the conversion range currently selected; a conversion range specifying circuit for enlarging the conversion range by one stage when a count value of the first range over signal generated within a fixed period is greater than a first predetermined value and narrowing the conversion range by one stage when a count value of the second range over signal generated with a fixed period is smaller than a second predetermined value.

22. In a reproducing apparatus having a second memory means for storing a digital sound signal; a second amplitude level detecting means for detecting an amplitude level which corresponds to amplitude information of the digital sound signal and outputting a digital amplitude signal which corresponds to the digital sound signal; a second conversion range selecting means for selecting a conversion range on a basis of the digital amplitude signal; a converting means for converting the digital sound signal into an analog sound signal in the conversion range selected by the second conversion range selecting means;

the improvement wherein said first conversion range selecting means comprises a comparator for generating a range over signal when a value of the digital amplitude signal is larger than a maximum value in the conversion range currently selected; a conversion range specifying circuit for enlarging the conversion range by one stage when a count value of the range over signal generated within a fixed period is greater than a predetermined value.

23. In a reproducing apparatus having a second memory means for storing a digital sound signal; a second amplitude level detecting means for detecting an amplitude level which corresponds to amplitude information of the digital sound signal and outputting a digital amplitude signal which corresponds to the digital sound signal; a second conversion range selecting means for selecting a conversion range on a basis of the digital amplitude signal; a converting means for converting the digital sound signal into an analog sound signal in the conversion range selected by the second conversion range selecting means;

the improvement wherein said second conversion range selecting means comprises a comparator for generating a range over signal when a value of the digital amplitude signal is larger than a maximum value in the conversion range one stage narrower than the conversion range currently selected; a conversion range specifying circuit for narrowing the conversion range by one stage when a count value of the range over signal generated within a fixed period is smaller than a predetermined value.

24. In a reproducing apparatus having a second memory means for storing a digital sound signal; a second amplitude level detecting means for detecting an amplitude level which corresponds to amplitude information of the digital sound signal and outputting a digital amplitude signal which corresponds to the digital sound signal; a second conversion range selecting means for selecting a conversion range on a basis of the digital amplitude signal; a converting means for converting the digital sound signal into an analog sound signal in the conversion range selected by the second conversion range selecting means;

the improvement wherein said first conversion range selecting means comprises a comparator for generating a range over signal when a value of the digital amplitude signal is larger than a maximum value in the conversion range currently selected and generating a second range over signal when the value of the digital amplitude signal is larger than the maximum value in the conversion range one stage narrower than the conversion range currently selected; a conversion range specifying circuit for enlarging the conversion range by one stage when a count value of the first range over signal generated within a fixed period is greater than a first predetermined value and narrowing the conversion range by one stage when a count value of the second range over signal generated within a fixed period is smaller than a second predetermined value.

Description Submit all comments and votes

FIELD OF THE INVENTION

The present invention relates to recording and reproducing methods and recording and reproducing apparatus.

BACKGROUND OF THE INVENTION

PCM (Pulse Coded Modulation) systems are conventionally known for use in the recording and reproducing of sound signals such as speech and music.

An improved PCM system, i.e., an ADPCM (Adaptive Differential Pulse Coded Modulation) system, is also known.

A PCM system suffers from the problem that the amount of information to be stored is large.

On the other hand, an ADPCM system suffers from the problem that since the differential data between adjacent sound data is stored, it is impossible to follow a waveform having an amplitude that abruptly changes.

SUMMARY OF THE INVENTION

Accordingly, it is an object of the present invention to provide recording and reproducing methods and apparatus that require the storage of only a small amount of information and which are capable of following even a waveform having an amplitude that abruptly changes.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1 and 2 are block diagrams of examples of the fundamental structure of the present invention;

FIG. 3 is an exemplary view of the principle of the present invention;

FIGS. 4 and 5 are block diagrams of a first embodiment of the present invention;

FIG. 6 is a block diagram which concretely shows a part of the first embodiment;

FIGS. 7 and 8 are block diagrams of a second embodiment of the present invention;

FIGS. 9 and 10 are block diagrams of a third embodiment of the present invention;

FIGS. 11(A-C) and 12(A-C) are block diagrams which concretely show a part of the third embodiment;

FIGS. 13 and 14 are block diagrams of a fourth embodiment of the present invention;

FIGS. 15 and 16 are block diagrams of a fifth embodiment of the present invention;

FIGS. 17 and 18 are block diagrams of a sixth embodiment of the present invention;

FIG. 19 is an explanatory view of the data structure of the data memory circuit in FIG. 18; and

FIG. 20 is an explanatory view of the principle of the sixth embodiment.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiments of the present invention will be explained hereinafter with reference to the accompanying drawings.

As shown in FIG. 3, the principle of the present invention is to convert an original sound signal (the waveform represented by the solid line) into a digital sound signal in a conversion range (indicated by the broken lines) selected in correspondence with the amplitude of the original sound signal. In other words, when the amplitude of the original sound signal is large, the original sound signal is converted in a conversion range having a large width, while the original sound signal is converted in a conversion range having a small width when the amplitude of the original sound signal is small, as shown in FIG. 3. For example, if a digital sound signal is composed of a constant number of bits irrespective of the amplitude of the original sound signal in any conversion range, recording and reproduction with the same sound quality is possible.

Examples of the basic arrangement of a recording apparatus and a reproducing apparatus according to the present invention will be explained with reference to FIGS. 1 and 2.

Although the recording apparatus shown in FIG. 1 and the reproducing apparatus shown in FIG. 2 may be independent of each other, the following explanation will be given on the assumption that the sound recorded by the recording apparatus shown in FIG. 1 is reproduced by the reproducing apparatus shown in FIG. 2, unless specified otherwise.

FIG. 1 is a block diagram of the example of the basic structure of a recording apparatus. The symbol IP represents an input means for outputting an original sound signal "a". In this embodiment, the input means IP is a microphone, an amplifier, etc., and inputs a sound such as speech and converts it into the original sound signal. The original sound signal is ordinarily an analog signal, but it may be converted into a digital signal.

The symbol SL1 represents a first selecting means for selecting a conversion range in correspondence with the amplitude of the original sound signal "a" output from the input means IP. The width of each conversion range is preferably selected so as to vary in geometrical progression. This is represented by the following equation:

wherein

A . . . width of each conversion range

A0 . . . width of the maximum conversion range

B . . . positive number smaller than 1

n . . . integer

For example, if it is assumed that B=1/2 in the above equation, the widths of the respective conversion ranges are 1/2.times.A0, 1/4.times.A0, . . . with respect to the width A0 of the maximum conversion range.

The symbol TR1 represents a first converting means for converting the original sound signal "a" into a digital sound signal in the conversion range selected by the first selecting means SL1, and outputting the digital sound signal "b1". The digital sound signal is ordinarily composed of a constant number of bits which do not vary with the conversion range.

The symbol MR1 represents a first memory means for storing the digital sound signal "b1" output from the first converting means TR1. The first memory means MR1 is generally composed of an RAM (Random Access Memory), etc.

The operation of the recording apparatus shown in FIG. 1 is as follows.

A sound such as speech and music is input to the inputting means IP. The sound is detected by the microphone, amplified by the amplifier and output as the original sound signal "a".

The first converting means TR1 converts the original sound signal "a" into digital data of a predetermined number of bits in the conversion range selected by the first selecting means SL1 at predetermined intervals and outputs the digital sound signal "b1". That is, the digital sound signal "b1" is obtained by subsequently converting the original sound signal "a" into digital data. The conversion range for this conversion is selected by the first selecting means SL1. The conversion range information d1 output from the first selecting means SL1 may be either the information indicating the width of the conversion range or the information for enlarging or narrowing the conversion range.

In this embodiment, the conversion range is selected by the first selecting means SL1 when the digital sound signal "b1" is input to the first selecting mans SL1. However, it is also possible to select the conversion range, for example, by inputting the original sound signal "a" to the first selecting means SL1. In other words, the signal for selecting the conversion range may be any signal which corresponds to the information on the amplitude of the original sound signal.

Each digital data of the digital sound signal "b1" output from the first converting mans TR1 is subsequently stored in the first memory means MR1.

FIG. 2 is a block diagram of the basic structure of a reproducing apparatus.

The symbol MR2 represents a second memory means for storing a digital sound signal. The second memory means MR2 is generally composed of ROM (Read Only Memory), etc. The digital sound signal is ordinarily composed of a constant number of bits which does not vary with the conversion range. The digital sound signal used in the recording means is preferably used as the digital sound signal stored in the second memory means MR2.

The symbol SL2 represents a second selecting mans for selecting a conversion range in correspondence with the information on the amplitude of a digital sound signal "b2" output from the second memory means MR2. The width of each conversion range is preferably selected in correspondence with the first selecting means SL1 in the recording apparatus. In other words, the width of each conversion range is preferably selected so as to vary in geometrical progression.

The symbol TR2 represents a second converting means for converting the digital sound signal "b2" into an analog sound signal "c" in the conversion range selected by the second selecting means SL2.

The symbol OP represents an outputting means for inputting the analog sound signal "c". In this embodiment, the outputting means OP is composed of an amplifier, a speaker, etc., and inputs the analog sound signal "c" and converts it into a sound output.

The operation of the reproducing apparatus shown in FIG. 2 is as follows.

Each digital data on the digital sound signal "b2" output from the second memory means MR2 is subsequently input to the second converting means TR2 and converted into the analog sound signal "c" in the conversion range selected by the second selecting means SL2. The conversion range information d2 output from the second selecting means SL2 may be either the information indicating the width of the conversion range or the information for enlarging or narrowing the conversion range.

In this embodiment, the conversion range is selected by the second selecting means SL2 when the digital sound signal "b2" is input to the second selecting means SL2. However, it is also possible to select the conversion range, for example, by inputting the analog sound signal "c" to the second selecting means SL2. In other words, the signal for selecting the conversion range may be any signal which corresponds to the information on the amplitude of the original sound signal.

The analog sound signal "c" output from the second converting means TR2 is input to the output means OP, amplified by the amplifier and output from the speaker as a sound.

In the example of the basic apparatus explained above, since the original sound signal is converted into the digital sound signal in the converting range selected in correspondence with the amplitude of the original sound signal at the time of recording, while the digital sound signal is converted into the analog sound signal in the converting range selected in correspondence with the amplitude of the digital sound signal at the time of reproduction, a recording apparatus and a reproducing apparatus are provided which require only a small amount of information to be stored and are capable of following a waveform having an amplitude that abruptly changes.

Each component of the recording apparatus and the reproducing apparatus described above will now be explained with reference to the following examples.

The structure of the following examples is the same as above discussed unless specified otherwise.

EXAMPLE 1

A first example of the invention based on the recording apparatus and the reproducing apparatus described above with reference to FIGS. 1 and 2 will be disclosed with reference to FIGS. 4 and 5, respectively.

Although the recording apparatus shown in FIG. 4 and the reproducing apparatus shown in FIG. 5 may be independent of each other, the following explanation will be given on the assumption that the sound recorded by the recording apparatus shown in FIG. 4 is reproduced by the reproducing apparatus shown in FIG. 5, unless specified otherwise.

Referring to FIG. 4, the inputting means IP, the first memory means MR1 and the first converting means TR1 are the same as those described with reference to FIGS. 1 and 2.

The first selecting means SL1 is comprised of a first amplitude level detecting means SD1 and a first conversion range selecting means TS1.

The first amplitude level detecting means SD1 detects the amplitude level which corresponds to the information on the amplitude of the original sound signal "a" output from the inputting means IP. In this embodiment, the digital sound signal "b1" is input to the first amplitude level detecting means SD1, as shown in FIG. 4. However, the signal input to the first amplitude level detecting means SD1 may be any signal that corresponds to the information on the amplitude of the original sound signal.

The first conversion range selecting means TS1 receives the amplitude level information detected by the first amplitude level detecting means SD1 and selects the optimum conversion range.

The operation of the recording apparatus shown in FIG. 4 is as follows.

The original sound signal "a" is input to the first converting means TR1 and subsequently converted into the digital data on the digital sound signal "b1" in the conversion range selected by the first conversion range selecting means TS1.

Each digital data on the digital sound signal "b1" is stored in the first memory means MR1 and is also subsequently input to the first amplitude level detecting means SD1, wherein the amplitude level is detected for each digital data.

Each amplitude level information detected for each digital data on the digital sound signal "b1" is subsequently input to the first conversion range selecting means TS1, and the optimum conversion range is selected on the basis of continuous information (e.g., for 128 bytes) on the respective amplitude levels.

Referring to FIG. 5, the outputting means OP, the second memory means MR2 and the second converting means TR2 of the reproducing apparatus are the same as those described with reference to the basic apparatus of FIGS. 1 and 2.

The second selecting means SL2 is comprised of a second amplitude level detecting means SD2 and a second conversion range selecting means TS2.

The second amplitude level detecting means SD2 detects the amplitude level which corresponds to the information on the amplitude of the digital sound signal "b2" output from the second memory means MR2. In this embodiment, the digital sound signal "b2" is input to the second amplitude level detecting means SD2, as shown in FIG. 5. However, the signal input to the second amplitude level detecting means SD2 may be any signal that corresponds to the information on the amplitude of the digital sound signal.

The second conversion range selecting means TS2 receives the amplitude level information detected by the second amplitude level detecting means SD2 and selects the optimum conversion range.

The operation of the recording apparatus shown in FIG. 5 is as follows:

Each digital data on the digital sound signal "b2" output from the second memory means MR2 is input to the second converting means TR2 and is also subsequently input to the second amplitude level detecting means SD2, wherein the amplitude level is detected for each digital data.

Each amplitude level information detected for each digital data on the digital sound signal "b2" is subsequently input to the second conversion range selecting means TS2, and the optimum conversion range is selected on the basis of continuous information (e.g., for 128 bytes) on the respective amplitude levels.

The second converting means converts the digital sound signal "b2" into the analog sound signal "c" in the conversion range selected by the second conversion range selecting means TS2.

Example of the first conversion range selecting means TS1, the second conversion range selecting means TS2, the first amplitude level detecting means SD1 and the second amplitude level detecting means SD2 and the operations thereof will now be explained.

The first conversion range selecting means TS1 and the second conversion range selecting means TS2 may have the same structure, and the first amplitude level detecting means SD1 and the second amplitude level detecting means SD2 may also have the same structure. These structures are shown in FIG. 6.

Each of the digital data b1 and b2 of the digital sound signals input to or output from the first conversion means TR1 and the second conversion means TR2 shown in FIGS. 4 and 5 is applied to a comparator 11.

The comparator 11 determines whether or not the value of the amplitude level contained in the digital sound signal b1 or b2 is larger than the maximum value (111 . . . 1) in the current conversion range and the maximum value (011 . . . 1) in the conversion range that is half as large as the current conversion range. If the value of b1 or b2 is larger than the maximum value of the current range, "1" is output to a terminal P1, while "1" is output to a terminal "P2" if the value of b1 or b2 is smaller than half the current range.

Every time "1" is output from the terminal P1 or P2 of the comparator 11, "1" is selectively added to the value of a separate counter of counter 12, in dependence upon whether the count was output from the terminal P1 or from the terminal P2. Every time an item of data is input to the comparator 11, "1" is added to the value of a counter 13 (having a number system with 128 as a base).

When the count stored in the counter 13 reaches "128", a first count value of the number of outputs P1 larger than the maximum value (111 . . . 1) in the current conversion range and a second count value of the number of outputs P2 larger than the maximum value (011 . . . 1) in the conversion range half as larger as the current conversion range are output from the counter 12. A comparator 14 compares the respective first and second count values with a first reference value (assumed to be "3") and a second reference value (assumed to be "3"), respectively. When the first count value of the counter 12 is not smaller than the first reference value "3", the conversion range of a conversion range specifying register 16 is enlarged by one stage. On the other hand, when the second count value of the counter 12 is not greater than the second reference value "3", the conversion range of a conversion range specifying register 16 is narrowed by one stage. As a result, the conversion range specifying register 16 outputs the optimum conversion range information d1 and d2.

The counter stored in the counter 12 is cleared via a delay circuit 15 by the output of the counter 13 after the end of the comparing operation of the comparator 14.

The recording apparatus and the reproducing apparatus in this embodiment can automatically select the conversion range set by the first conversion range selecting means TS1 and the second conversion range selecting means TS2. Since automatic selection of the conversion range is possible, it is unnecessary to store the conversion range information in the first memory means MR1 and the second memory means MR2, thereby enabling the reduction of the storage capacity.

EXAMPLE 2

A second embodiment based on the recording apparatus and the reproducing apparatus described above with reference to the basic arrangement of FIGS. 1 and 2 will be disclosed with reference to FIGS. 7 and 8.

Although the recording apparatus shown in FIG. 7 and the reproducing apparatus shown in FIG. 8 may be independent of each other, the following explanation will be given on the assumption that the sound recorded by the recording apparatus shown in FIG. 7 is reproduced by the reproducing apparatus shown in FIG. 8, unless specified otherwise.

The inputting means IP, the first memory means MR1 and the first converting means TR1 are the same as those described above with reference to the basic arrangement of FIGS. 1 and 2.

The first selecting means SL1 comprises a third amplitude level detecting means SD3, a third conversion range selecting means TS3 and a control data inserting means CDI.

The third amplitude level detecting means SD3 and the third conversion range selecting means TS3 are similar to the first amplitude level detecting means SD1 and the first conversion range selecting means TS1 described above with reference to Example 1.

The control data inserting means CDI inserts the information on the conversion range selected by the third conversion range selecting means TS3 into each digital data on the digital sound signal "b1" which is output from the first converting means TR1.

The operation of the recording apparatus shown in FIG. 7 is as follows.

The original sound signal "a" is input to the first converting means TR1 and subsequently converted into the digital data on the digital sound signal "b1" in the conversion range selected by the third conversion range selecting means TS3.

Each digital data of the digital sound signal "b1" is input to the control data inserting means CDI and is also subsequently input to the third amplitude level detecting mans SD3, wherein the amplitude level is detected for each digital data.

The third conversion range selecting means TS3 carries out a similar operation to that in Example 1 explained in FIG. 6 so as to select the conversion range.

The control data inserting means CDI carries out one of the following operations (1) to (3).

(1) To insert conversion range information for each digital data of the digital sound signal "b1".

(2) To insert conversion range information for every predetermined number of items of digital data of the digital sound signal "b1". For example, conversion range information of 1 byte is inserted for every 128 bytes of digital data of the digital sound signal "b1".

(3) To insert conversion range information every time the conversion range changes.

The data to be inserted in the operations (1) to (3) may be either a conversion range itself or information for enlarging or narrowing the conversion range.

The conversion range information output from the control data inserting means CDI is output together with the digital sound signal and stored in the first memory means MR1.

FIG. 8 is a block diagram of a second embodiment of the reproducing apparatus.

The outputting means OP, the second memory means MR2 and the second converting means TR2 are the same as those described with reference to the basic arrangement of FIGS. 1 and 2.

The second selecting means SL2 comprises a control data extracting means CDO and a fourth conversion range selecting means TS4.

The control data extracting means CDO extracts the conversion range information which is output together with the digital sound signal from the second memory means MR2.

The fourth conversion range selecting means TS4 selects the conversion range on the basis of the conversion range information extracted by the control data extracting means CDO.

The operation of the recording apparatus shown in FIG. 8 is as follows.

The second memory means MR2 outputs conversion range information together with the digital sound signal. The conversion range information extracted by the control data extracting means CDO is supplied to the fourth conversion range selecting means TS4. The digital sound signal is supplied to the second converting means TR2 and converted into the analog sound signal "c" in the conversion range selected by the fourth conversion range selecting means TS4.

The data stored in the first memory means MR1 shown in FIG. 7 is stored in the