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What is claimed is:
1. An improved signal recording apparatus of the type in which a plurality
of fields of video signals are sequentially recorded on a corresponding
plurality of concentrically arranged tracks on a rotary recording medium,
and selected ones of the remaining tracks on the recording medium are
arranged to have audio signal segments recorded thereon, some of which are
intended to be reproduced sequentially, wherein the improvements in the
recording apparatus comprise:
(a) means for time-compressing the audio signal segments;
(b) means for generating control code data for controlling a reproduction
sequence of audio signal segments recorded in said plurality of recording
tracks; said control code data including address data indicating a track
number and address on said rotary recording medium, data for
discriminating whether a track being reproduced is one of the tracks
having an audio signal segment which is intended to be reproduced in a
sequence with other recorded audio signal segments, and data indicating a
track number of a video signal segment corresponding to the audio signal
segment being reproduced;
(c) table memory means for storing said control code data including said
address data, said discriminating data and said track number data;
(d) means for recording said control code data in predetermined portions of
said respective audio tracks together with said time compressed audio
data; and
(e) means for recording said control code data stored in said table memory
means on a control track at a predetermined location on said rotary
recording medium.
2. A signal recording apparatus according to claim 1, wherein the means for
recording said control code data reads out said control code data stored
in said table memory means and records it on said control code track when
the recording of said time-compressed audio signal segment and said video
signal segment for a given scene corresponding thereto is completed.
3. A signal recording apparatus according to claim 1, wherein the means for
recording said control code data reads out said control code data stored
in said table memory means and records it on said control code track when
the recording of said time-compressed audio signal segment and said video
signal segment for a given series of scenes corresponding thereto is
completed.
4. A signal recording apparatus according to claim 2 in which said control
code data stored in said table memory means is read out and recorded on
said control code track before said rotary recording medium is removed
from said recording apparatus.
5. A signal recording apparatus according to claim 1, in which said means
for time compressing said audio signal segments includes audio signal
memory means, means for inputting audio data in digital form into said
audio signal memory means, a write/read address counter for controlling
said audio signal memory means; first and second clock signal generators
for respectively generating first and second clock signals and supplying
them to said write/read address counter, said first clock signal
corresponding to a selected clock frequency and having a frequency
substantially less than said second clock frequency, whereby said
write/read address counter generates write addresses at said first
frequency and read addresses at said second frequency whereby said digital
audio signal segments are written into said audio signal memory means at
said first clock signal frequency and are read out of said audio signal
memory at the higher, second clock signal frequency.
6. Apparatus according to claim 5, in which said second clock signal
generator produces said second clock signal at a frequency 640 times that
of said first clock signal.
7. In combination with a rotary recording medium on which a plurality of
fields of video signals are sequentially recorded on a corresponding
plurality of concentrically arranged tracks on said rotary recording
medium, and selected ones of the remaining tracks on the recording medium
are arranged to have time compressed audio signal segments and control
code data signals recorded thereon, said control code data signals
including address data indicating a track number and address on said
rotary recording medium and data for discriminating whether a track being
reproduced is an audio track or a video track, a signal reproducing
apparatus of the type which reproduces signals from said rotary recording
medium, the reproducing apparatus comprising:
(a) decoder means for initially reproducing said control code data signals
from the remaining tracks upon the beginning of reproduction;
(b) table memory means for storing control code data from said decoder
means, said control code data including said address data, said
discriminating data and said track number data;
(c) display means for displaying the control code data stored in said table
memory means;
(d) means for selectively thereafter reading said video data and said time
compressed audio data from said rotary recording medium in accordance with
the display control code data; and
(e) means for time-expanding the time compressed audio signal segments read
from said rotary recording medium.
8. In a method of sequentially recording a plurality of fields of video
signals on a plurality of concentrically arranged tracks on a rotary
recording medium and audio signal segments, some of which are intended to
be reproduced in sequence, on selected ones of the remaining tracks on the
recording medium, the improvement comprising the steps of:
(a) time-compressing the audio signal segments before recording them;
(b) generating control code data for controlling a reproduction sequence of
audio signal segments recorded in said plurality of recording tracks; said
control code data including address data indicating a track number and
address on said rotary recording medium, data for discriminating whether a
track being reproduced is one of the tracks having a sequential audio
signal segment, and data indicating a track number of a video signal
segment corresponding to the audio signal segment being reproduced;
(c) storing said control code data including said address data, said
discriminating data and said track number data;
(d) recording said control code data in predetermined portions of said
respective audio tracks together with said time compressed audio data; and
(e) recording said stored control code data on a control track on said
rotary recording medium.
9. A method of signal recording according to claim 8, wherein the step of
recording said control code data includes the steps of reading out said
stored control code data and recording it on said control track when the
recording of said time-compressed audio signal segment and said video
signal segment for a given scene corresponding thereto is completed.
10. A method of signal recording according to claim 8, comprising the
further steps of reading out said stored control code data and recording
it on said control track before said rotary recording medium is removed
from said recording apparatus.
11. A method of signal recording according to claim 8, wherein the step of
time compressing said audio signal segments includes the further steps of
generating first and second clock signals, said first clock signal
corresponding to a selected clock frequency and having a frequency
substantially less than said second clock frequency, and writing said
audio signal segments into a digital memory at said first clock frequency
and reading out said audio signal segments from the digital memory at said
second clock frequency.
12. A method of signal recording as recited in claim 11, wherein said
second clock signal has a frequency 640 times that of said first clock
signal.
13. A signal reproducing method for use with a rotary recording medium on
which a plurality of fields of video signals are sequentially recorded on
a plurality of concentrically arranged tracks on said rotary recording
medium, and selected ones of the remaining tracks on the recording medium
are arranged to have time compressed audio signal segments and control
code data signals recorded thereon, said control code data signals
including address data indicating the track numbers of related audio and
video tracks on said rotary recording medium and data for discriminating
whether a track being reproduced is an audio track or a video track, the
signal reproducing method comprising the steps of:
(a) initially reproducing said control code data from the remaining tracks;
(b) storing said reproduced control code data, said control code data
including said address data, said discriminating data and said track
number data;
(c) displaying the stored control code data and selectively controlling a
reproduction sequence of said audio and video signals recorded in said
plurality of recording tracks in accordance with the displayed control
code data; and
(d) time-expanding the reproduced, time compressed audio signal segments. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to a recording apparatus and method in which voice
or audio signal recording tracks and video signal recording tracks can be
recorded together on one and the same recording medium.
2. Description of the Prior Art
The present Applicant has already proposed in the U.S. patent application
No. 06/791152, filed on Oct. 24, 1985 or in European Laying- open
Publication No. 180477, published on May 7, 1986, a so-called electronc
still camera adapted for recording a still image on picture, by means of
which the voice can be recorded simultaneously with the still image or
picture. On a disk recorded on such on electronic still camera having the
function of voice recording, there are formed video signal tracks and
voice or audio signal tracks in co-existence with one another. As for the
recording states of audio signals, some are terminated in one track, while
others are extended over plural tracks. Also, there may exist or may not
exist video signals corresponding to the audio signals. The information
concerning these recording states are recorded in a control data recording
area in the audio signal tracks. Thus, when a series of audio signals are
recorded over plural tracks, the leading track number or address and the
next following track number or address are recorded in the aforementioned
control data recording area. When there exist corresponding video signals,
the number or address of the video track is recorded in the aforementioned
control data recording area.
It is noted that the recording format of the video signal track is not
designed to keep a record in the video data of address data concerning the
track of the corresponding audio signals. Therefore, in reproducing the
disk on which video and audio tracks exist together, when the video track
on the disk is reproduced first by the reproducing head, it may be
impossible to reproduce corresponding audio signals simultaneously with
the video signals, even if these audio signals are present on the disk.
Similar inconveniences are caused when there exist a plurality of sets of
audio signals extending over plural tracks and a given sequence or a train
of voice sounds accompanying a still image or scene is terminated to enter
into the next sequence.
SUMMARY OF THE INVENTION
In view of the foregoing, it is a principal object of the present invention
to provide a recording apparatus and method wherein control data
concerning all the tracks on the disk including the aforementioned track
number are densely recorded on a control track on the disk in such a
fashion that, during reproduction, this control track is reproduced and a
series of audio signals or corresponding video signals are optionally
selected to permit smooth and prompt reproduction of the recorded contents
of the disk.
For accomplishing the above object, the present invention provides a
recording apparatus and method wherein at least the audio signal recording
tracks and video signal recording tracks can be recorded together on one
and the same recording medium, information signals including leading and
next following track numbers concerning temporarily continuous audio
signals recorded over plural tracks and track numbers for recording video
signals corresponding to the audio signals are recorded on at least the
audio signal recording track, there is provided a digital, table memory
for storing the track number data of the information signals, and wherein
the track number data in the table memory are subsequently recorded in a
predetermined control recording track on the recording medium.
In reproducing the disk bearing these information signals, all the
recording tracks on the disk are scanned for reproducing at least said
information signals, these reproduced information signals are then written
into corresponding table positions in a digital, table memory and the
subsequent process of reproduction of the audio and video tracks is
thereafter controlled on the basis of these written information signals,
so that editing of the recorded information is facilitated.
In this manner, track number data recorded on the predetermined record
track are read prior to reproduction such that track management during
reproduction is facilitated and reproduction or editing of a sequence
consisting of a series of audio signals or corresponding video signals can
be performed smoothly and promptly.
The foregoing and other objectives, features and advantages of the
invention will be more readily understood upon consideration of the
following detailed description of certain preferred embodiments of the
invention, taken in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a diagrammatic block diagram showing a recording apparatus
according to an embodiment of the present invention.
FIG. 2 shows a recording format for one-sector of audio signals.
FIG. 3 is a diagrammatic plan view showing the audio and control tracks on
the disk.
FIGS. 4(a) to (c) show different examples of the possible organization of
the table data within the table memory.
FIG. 5 diagrammatically shows an example of the contents of the recording
tracks on the disk.
FIG. 6 shows an example of the recording format on the control track.
FIG. 7 is a block diagram showing an example of the reproducing block in
FIG. 1.
FIG. 8 is a block diagram showing an example of the reproducing apparatus
adapted for reproducing the disk recorded by the recording apparatus.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1 shows in a block diagram a recording apparatus according to an
embodiment of the present invention wherein the audio or voice signal
recording track or "audio track" and the video signal recording track or
"video track" can be recorded in co-existence on a unitary disk used as a
recording medium. The technology disclosed in this block diagram is
basically the same as that disclosed in the aforementioned U.S. patent
application No. 06/791152.
Referring to this figure, video signals for one picture or field to be
recorded are supplied to an input terminal 1 and converted in a recording
circuit 2 into predetermined recording signals. These recording signals
are then transmitted via a pre-emphasis circuit 3 of non-linear
characteristics and a changeover switch 4 to a frequency modulation
circuit 5, where they are converted into frequency modulated signals (FM
signals). These FM signals are then transmitted to a magnetic head 6 so as
to be recorded as video track VT on a disk D rotationally driven at e.g.
3600 rpm by an electric motor M.
Meanwhile, audio signals are supplied to an input terminal 11 and thence to
an analog/digital conversion circuit (A/D converter) 13 through an encoder
12 intended for noise reduction. These signals are converted in this A/D
conversion circuit 13 into digital signals that are then written into a
digital memory 14. The signals read out from the digital memory 14 are
transmitted to a digital/analog conversion circuit (D/A converter) 15 for
conversion into analog signals. At this time, clock signals of the
frequency f.sub.c used for sampling audio signals of, for example, the
band width of 5 kHz, are supplied from an oscillator 21 to the A/D
converter 13, while being also supplied to an address counter 22 adapted
for driving and controlling the memory 14.
In the present embodoment, clock signals f.sub.o, having a frequency equal
to about 640 times the frequency f.sub.c of the sampling clock signals, or
640 f.sub.c, are supplied from oscillator 23 to the D/A converter 15,
while being also supplied to the address counter 22. Meanwhile, pulse
signals at intervals of a one-sixtieth of a second based on the rotational
phase of the disk as sensed by a pickup head 24 with each rotation of a
magnetic piece G mounted on a rotary driving arbor of the disk D, are
supplied to a timing signal generating circuit 25. On the basis of these
pulse signals, timing signals are produced in the timing signal generator
25 so as to be supplied to the address counter 22. These timing signals
from the timing signal generator 25 are also transmitted to an
identification signal generator 26 to be later described and to an encoder
33. Shutter button actuating signals are generated by actuating a shutter
button switch, not shown, and supplied at terminal 27 to the timing signal
generator 25.
Thus the audio signals converted into corresponding digital signals at the
A/D converter 13 in accordance with the sampling signals from the
oscillator 21, are written into memory 14 with these sampling signals as
write clock signals. At this time, these audio signals are written into
the memory 14 by a sector or segment of a duration of e.g. 2.5 seconds,
which is a quadrisection of 10 seconds. In the present embodiment, the
written signals are read out from the memory 14 in accordance with signals
from the oscillator 23 at a rate 640 times that used at the time of
writing. Stated differently, the audio signals of the duration of 2.5
seconds are compressed along their time axis by a factor of 1/640, that
is, into signals of the duration of 2.5/640.apprxeq.3.9 millisecond. These
audio signals compressed along the time axis correspond to the audio
signals shown in FIG. 2 as later described. During this read-out time, the
audio signals corresponding to the sectors SA, SB, SC and SD on the disk D
of FIG. 3 as later described are read out on the basis of the pulse
signals of a 1/60-second period from the pickup head 24 and at a timing
sequentially dephased by one quarter of a period or by 1/240-second for
each 25 seconds.
The audio signals read-out from memory 14 are converted in the D/A
converter 15 into corresponding analog signals as described hereinabove
before being transmitted to a signal mixer 16. To the signal mixer 16 are
supplied start identification signals SID and end identification signals
EID produced in an identification signal generator 26 on the basis of the
timing signals from the timing signal generator 25. To the signal mixer 16
are also supplied via encoder 33 information signals API produced in an
information signal generator 32 on the basis of control signals from a
system controller 31. These information signals consist of the control
code used for controlling the reproducing operation of the audio signals
and are mixed in the mixer 16 for producing a signal having the pattern
shown in FIG. 2. This figure shows one-sector signal consisting of a
time-axis-compressed audio signal AS, start identification signal SID
towards the front of the signal AS, end identification signal EID towards
the rear of the signal AS, and the information signal API between the
signals SID and AS, this information signal being used for controlling the
reproducing operation of the audio signals.
It is noted that the control code data of the information signal API are
comprised at least of the currently reproduced track number Nt, a leading
track number Nf and a next following track number Nn in the case of a
continuous voice over plural tracks as well as the video track number on
which corresponding video signals are recorded (corresponding track number
Nc). The code data may also include data concerning the sector-using
status and the time axis compression mode, if required. The track numbers
Nf and Nn indicate the number of a track Nf in which the leading portion
of a series of temporary continuous audio signals are recorded when these
signals are recorded over plural tracks and the number of a track Nn in
which the portion consecutive to the currently recorded portion of the
audio signals is to be recorded, respectively.
From the mixer 16 of FIG. 1 are outputted the aforementioned sector format
signals shown in FIG. 2, these signals being transmitted via linear
preemphasis circuit 17 and changeover switch 4 to the frequency modulating
circuit 5. The signals from the circuit 5 are transmitted to the magnetic
head 6 so as to be recorded at a rate of 4 sectors per track on the disk
D. That is, four sectors SA, SB, SC and SD are recorded on one audio track
AT on the disk D.
During recording of the aforementioned video and audio signals, head
position control signals are supplied from system controller 31 through a
head driving circuit 35 to a head driving electric motor 36. The magnetic
head 6 is driven and controlled by the motor 36 so as to be thereby
positioned e.g. at a track on the disk D corresponding to the current
track number Nt. The aforementioned leading track number Nf, next
following track number Nn and the corresponding track number Nc are
transferred to and stored in a digital, table memory 38 for forming a
table such as shown in FIG. 4. On at least one track, "control track" CT,
at a predetermined position on the disk D, as at an outermost or innermost
position thereof, there are recorded so-called control data, shown in FIG.
3 such as the track number information stored in the memory table 38.
Referring now more particularly to FIG. 4 there is shown an example of the
table memory 38. Each memory block corresponding to each track is composed
of 26 bits b.sub.6 to b.sub.25, with the 6 bits b.sub.0 to b.sub.5 being
assigned to its own track number Nt, the bit b.sub.6 indicating whether
the track is an audio signal record track AT and the bit b.sub.7
indicating whether the track is a video signal record track VT. The six
bits b.sub.8 to b.sub.13 are assigned to the leading track number Nf of
the audio information, the six bits b.sub.14 to b.sub.19 are assigned to
the next following track number Nn of the audio information and the six
bits b.sub.20 to b.sub.25 are assigned to the aforementioned corresponding
track number Nc.
When a plurality of these audio tracks correspond to a single video track,
the track number of the associated video track is entered only into the
address of an optionally selected single audio track. Conversely, in the
address corresponding to a video track, the track number of one of the
associated audio tracks is entered. The table memory 38 has a capacity
corresponding to the number of the tracks on the disk, such as 50 tracks,
except the aforementioned control track. To these fifty blocks, there are
sequentially affixed addresses, such as the addresses 0 to 49.
During recording of the video or audio signals, the number Nt of the
currently recorded track, the bits indicating whether the track is an AT
or VT, the leading track number Nf, the next following track number Nn and
the corresponding track number Nc are written in each block at the
respective predetermined bit positions, starting from the block of the
more junior address number.
FIG. 4A shows the contents of the memory table in the instance wherein the
recording on the record tracks on the disk D is performed in the sequence
shown for example in FIG. 5. Referring to these figures, in connection
with a single video signal being recorded in the fifth track, a track
number `5` is written into a bit area b.sub.0 to b.sub.5 of the track
number Nt of the block bearing the address 0. The bit b.sub.6 for AT is
`0`, the bit b.sub.7 ; for VT is "1", and the bit areas Nf, Nn and Nc are
all `0`. Next, in connection with the video signal being recorded in the
sixth track and the corresponding audio signals being recorded in the
seventh track, data concerning the track number Nt=6 is written into the
block of the address 1, while that concerning the track number Nt=7 is
written into the block of the address 2. In this manner, the table shown
in FIG. 4A is sequentially formed in accordance with the recording
sequence on the disk D shown in FIG. 5.
After the end of recording, just prior to taking out the disk D from the
device or just prior to power turn off, the data on the table of FIG. 4A
are recorded as so-called control data on the control track CT on the disk
D. It will be noted that, although the data can be written on the control
track CT each time each sequence is terminated, by starting from the
junior address number in regular order, it is also possible to record the
data at a time after the recording of the series of sequences such as
those for 50 tracks is terminated. Taking the instance of FIG. 5 as an
example, while the data can be written after each sequence such as [1, 2,
3, 4], [5], [6, 7] or [8, 9] is terminated, it is also possible to record
the data at a time after a series of sequence such as [1, 2, 3, 4 . . . ,
P, 11, 12, 13] are terminated.
It is also noted that, as shown in FIG. 5, the data order on the disk is
not necessarily constant but may frequently be disturbed in the course of
the repetitive recording, erasing and reproducing operations.
As shown in FIG. 6, the control track CT is divided into 50 segments
SG.sub.0 to SG.sub.49 corresponding to the tracks such as the 50 tracks on
the disk D. In each of these segments, there comes first an area for sync
signals, followed by record areas for the data Nt, AT, VT, Nf, Nn and Nc
corresponding to one block in the table memory. In this case, it can be
considered that the segment SG k of an address k corresponds to the block
bearing the address k in the aforementioned table memory and that the data
in the block are recorded in the segment SG k.
During recording of the table data in the control track CT, the data in a
table memory 38 is read out by the system controller 31 and an information
signal generator 32 so as to be processed into control data signals, that
is, signals having the format shown in FIG. 6. These control data signals
are transmitted via encoder 33 and mixer 16 to preemphasis circuit 17. The
output signals from the preemphasis circuit 17 are transmitted via
changeover switch 4 to FM circuit 5. Simultaneously, head position control
signals from the system controller 31 are transmitted via head driving
circuit 35 to the head driving electric motor 36 such that the magnetic
head 6 is shifted to a position of the control track CT on the disk D,
such as a position of the outermost track on the disk. The signals from
the FM circuit 5 are supplied to the magnetic head 6 for recording on the
control track.
As will be described in further detail hereinafter, prior to the recording
on the control track CT, the data order in the table memory 38 can be
selectively rearranged so that the track number sequence is as shown for
example in FIGS. 5 and 4A (organized by recording sequence), FIG. 4B
(organized by track number Nt) or FIG. 4C (organized by leading track
number Nf).
It is now assumed that a disk D is only partially recorded and recording is
to be performed on a vacant or unrecorded track. In this case, after the
disk D has been loaded into a recording apparatus such as an electronic
still camera and the camera is switched from the power turn off state to
the standby state for recording, at least the control track CT is
reproduced by a reproducing block 40, the control data such as the track
number etc. are read out by the information signal sensor 45, and the thus
read-out data are written into the table memory 38 through system
controller 31.
The reproducing block 40 is constructed for example as shown in FIG. 7. The
reproducing signals from a reproducing magnetic head 41, which can be the
same as the magnetic head 6, are frequency demodulated in a frequency
demodulator 42 before being transmitted to a decoder 44, which has
characteristics that are reverse to those of the encoder 33, by way of a
de-emphasis circuit 43, which has characteristics that are reverse to
those of the preemphasis circuit 17 of the aforementioned voice recording
system. The output signals from the decoder 44 are supplied to the
information signal sensor circuit 45 shown in FIG. 1.
This feature is useful for an electronic still camera of the type in which
the disk can be mounted or dismounted after partial recording on the disk
D is terminated, or of the type in which the data stored in the table
memory 38 is erased at the time of power turn off. The using or recording
state of the recording tracks on the disk D is written at all times in the
table memory 38 before the signal recording, resulting in better track
control or management and prevention of the inconvenience that new signals
are inadvertently recorded on the pre-recorded tracks.
EXAMPLE OF THE REPRODUCING APPARATUS
When reproducing the disk D bearing the aforementioned recording, a
reproducing apparatus such as shown in FIG. 8 may be used.
Referring to this figure, prior to reproduction of the audio or video
signals, the system controller 124 operates to shift the magnetic head 101
to the predetermined position of the control track CT through the head
driving circuit 108 and the head driving electric motor 109 in such a
manner as to reproduce the control data including the aforementioned track
number data recorded on the control track CT. Thus the reproducing signals
from the magnetic head 101 obtained upon scanning the control track CT are
transmitted via frequency demodulating circuit 102 and deemphasis circuit
111 to an information signal sensor 122. The reproducing signals are
processed by the information signal sensor 122 into data signals
indicating the track number Nt, Nf, Nn and Nc in the table so as to be
sequentially written by system controller 124 in the associated positions
of the digital, table memory 131. In this case, the table memory 131
consists of 50 blocks each containing 26 bits similarly to the
aforementioned memory 38. When the record contents of the segments
SG.sub.0 to SG.sub.49 of the control track CT are written into the blocks
of the addresses 0 to 49 of the control track CT, respectively, the table
as shown for example in FIG. 4A is formed in the table memory 131. Thus,
in a dual type apparatus that can be used simultaneously as a recording
unit and as a reproducing unit, a table memory can be used in common to
these units.
The contents of the table shown in FIG. 4 are read out from memory 131 via
system controller 124 so as to be displayed in a monitor output device 132
such as a CRT display device. In this case, the table per se shown in FIG.
4A or a portion thereof can be displayed. By consulting the table display,
the user or operator can use a keyboard input device 133 to select the
image and voice of the desired sequence and then perform a data inputting
operation to the system controller 124 for reproducing the selected voice
and image. It is noted that display of the reproducing image and the data
from the system controller 124 can be effected by using the same monitor
outputting device 132.
It is assumed that the track number Nt of the table of FIG. 4 is to be
designated as an example of the reproducing operation by the keyboard
inputting device 133. The system controller 124 reads the memory block of
the designated track number Nt on the table of FIG. 4 in the table memory
131. If the designated track is the audio track, system controller 124
controls the head driving circuit 108 for sequentially reproducing from
the track of the leading track number Nf such that a series of audio
signals corresponding to the sequence including the designated track are
reproduced.
If the designated track is a video track, since the leading track number Nf
of the corresponding audio signal is written into the associated memory
block of the table, the sequence can be reproduced from the leading part
thereof. In the table shown in FIG. 4, since the tracks are organized by
units of sequences, the track can be designated by specifying the sequence
number, which may for example be the leading track number Nf itself or a
new number in accordance with the recording order shown in FIG. 5. In this
manner, the desired sequence can be reproduced instantaneously.
In this case, the contents of the table memory can be displayed on a
minotor 132, as shown in FIG. 4A or, after sorting, in the order of the
track number Nt as shown in FIG. 4B. Such sorting can also be in the order
to the leading track numbers of the voice sequence as shown in FIG. 4C.
The order of display can be changed in accordance with the operation that
is performed on the keyboard 133. It is noted that, in FIGS. 4A to 4C,
there is shown various alternative states of the data contents
corresponding to the addresses in the table memory 131, these data
contents being displayed directly. However, it is also possible to provide
a separate buffer memory, with the contents of table memory 131 being
constant at all times and the data contents in the buffer memory being
display with the changes in the order of the display.
The other components of the reproducing apparatus shown in FIG. 8 are
provided for performing an operation which is the reverse of the
aforementioned operation of the recording apparatus shown in FIG. 1 for
restoring the original video or audio signals before recording thereof.
Thus, referring to FIG. 8, signals reproduced by the magnetic head 101 from
the disk D are transmitted to a frequency demodulating circuit 102. When
the magnetic head 101 is scanning over the video track VT bearing the
recorded video signals, demodulated signals are taken out as video signals
at the output terminal 105 through the reproducing circuit 104 and a
deemphasis circuit 103 having non-linear characteristics.
When the magnetic head 101 is scanning the track bearing the recorded audio
signals, demodulated signals are supplied via deemphasis circuit 11 of
linear characteristics to an A/D converter 112 while also being supplied
to an identification signal sensor circuit 121 and an information signal
sensor circuit 122. The start identification signal SID and end
identification signals EID sensed at an identification signal sensor 121
are supplied to a timing signal generator 123. The start identification
signals SID are supplied to the information signal sensor circuit 122,
while the information signals API controlling the reproducing operation of
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