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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an apparatus for recording and reproducing
a still image from, for example, a still video camera, and more precisely,
it relates to a recording method of a i.e., still video apparatus (still
image recording and play-back apparatus) in which sound signals can be
recorded and reproduced.
2. Description of Related Art
In a still video apparatus, a unit of one or two recording tracks, out of a
plurality of recording tracks provided on a magnetic disc, forms one field
picture plane or one frame picture plane. In a still video apparatus in
which sound signals can be recorded, a sound lasting from 5 to 20 seconds
can be recorded on one track. Since one turn of the magnetic disc
corresponds to one field of the image signal (about 1/60 second in the
case of an NTSC system), upon recording, sound signals to be recorded
within a predetermined time are first stored in a memory means, and then,
the time base of the stored sound signals are compressed so that they may
be read and recorded on the magnetic disc. Accordingly, a known still
video apparatus is usually provided with an image release switch which is
actuated to record a picture, a sound collecting switch which is actuated
to store a sound in the memory means, and a sound release switch which is
actuated to record the stored sound onto the magnetic disc.
In a recent still video apparatus, a recording system in which the image
signals and the sound signals are recorded in a corresponding fashion has
been adopted, which system will be referred to hereinafter as an AV
(Audio-Visual) mode. In this AV mode type of recording lo system, for
example, the tracks of the magnetic disc for the image signals and the
sound signals are preset, so that when the image signals or the sound
signals are recorded, data signals including the corresponding sound
signals or image signals and discrimination marks which differentiate the
presence of the corresponding image signals or sound signals, are recorded
on the respective tracks. Upon reproducing the sound and image signals,
the discrimination marks are reproduced to carry out the necessary
operations in accordance with the reproduced discrimination marks. The
data signals are subject to DPSK modulation and overlapped on the image
signals so as to be recorded together.
In a known first recording method in the AV mode, first the storage of the
sound signals in the memory means commences, and when the image release
switch is actuated during the storage of the sound signals, the image
signals are recorded. When the storage of the sound signals is complete,
the stored sound signals are recorded.
In a known second recording method in the AV mode, when the image release
switch is actuated, the image signals are first recorded, and thereafter,
the storage of the sound signals automatically begins. When the storage of
the sound signals is complete, the stored sound signals are automatically
recorded.
However, in the first recording method, since the image signals are
recorded during the storage of the sound signals, sounds produced when the
diaphragm or shutter are driven upon operation of the image release switch
may be recorded as noise, or the sound signals can be deteriorated by a
fluctuation of the sound signal level due to a voltage drop caused by the
commencement of the magnetic disc rotation or the emission of strobe
light.
In the second recording method, since the sound signals are automatically
recorded after the image signals are recorded, undesirable sound may be
recorded, or conversely, desirable sounds may not be recorded.
Furthermore, in both the first and second recording methods, since the
sound signals are recorded to correspond to the recorded image signals in
the AV mode, in order to stop the recording of the sound signals after the
completion of the recording of the image signals, it is necessary to
actuate a mode selection switch to switch to the AV mode. To this end, to
continuously record the image signals without temporarily recording the
sound signals in the AV mode, the mode selection switch must be
troublesomely actuated.
In addition to the foregoing, in the known recording methods mentioned
above, after-recording in which the sound is recorded after the picture is
recorded in the AV mode without changing the mode cannot be effected.
Accordingly, it is necessary to record only the image signals in the
normal mode, and then record the sound signals on the tracks of the
corresponding image signals. This is troublesome.
The primary object of the present invention is to provide a recording
apparatus and method which can eliminate the above mentioned drawbacks of
the prior art.
SUMMARY OF THE INVENTION
To achieve the object mentioned above, according to the basic concept of
the present invention, if the image release operation is effected in the
AV record mode during the receipt of the sound signals, the receipt of the
sound signals is stopped and the image signals picked-up by the image
release operation are recorded. The sound signals received up until the
image release operation are then recorded on the recording medium.
If the image release operation is effected without receiving the sound
signals, the image signals are recorded and the mode is transferred to the
sound receipt waiting (standby) mode, in which the control waits for the
sound release in the AV record mode. If the sound release operation is
effected while in the waiting mode, the received sound signals are
recorded on the area of the recording medium corresponding to the area in
which the image signals are recorded.
If the image release operation is effected while in the waiting mode
without effecting the sound release operation, the sound signals are not
recorded on the area corresponding to the image signals recorded
immediately before the transfer to the waiting mode. In this case, the
image signals can be recorded on the adjacent area, so that the mode is
transferred to the waiting mode.
If, an operation other than the sound release operation or the image
release operation is effected while in the waiting mode, the sound signals
preferably are not recorded on the area corresponding to the recorded
image signals and the waiting mode is released.
According to the present invention, since the sound signals received before
the image release operation are recorded to correspond to the image
signals, the sound signals are free from adverse influence caused upon
image releasing.
Furthermore, since the mode is automatically transferred to the sound
receipt waiting mode when the image release operation is effected before
the sound signals are received, an operator can record the necessary sound
signals any time after the image signals are recorded without modifying
the mode (so-called "after-recording").
On the other hand, if the image release operation is effected while in the
sound receipt waiting mode, the image signals are recorded on the next
image recording area, and thereafter, the mode is again returned to the
waiting mode. If another operation is effected, the waiting mode is
automatically released. Accordingly, a mode change operation is not
necessary.
The present disclosure relates to subject matter contained in Japanese
patent application No. HEI 02-306019 (filed on Nov. 14, 1990), which is
expressly incorporated herein by reference in its entirety.
BRIEF DESCRIPTION OF THE DRAWINGS
Below, a detailed explanation will be made of the present invention based
on embodiments shown in the attached drawings, in which:
FIG. 1 is a block diagram of an internal circuit of a still video camera to
which the present invention is applied, by way of example;
FIG. 2 is a perspective view of a still video camera shown in FIG. 1 as
viewed from behind;
FIGS. 3A and 3B are front elevational views of display surfaces of LCD
panels provided in a camera body and a sound adaptor, respectively;
FIGS. 4A, AB and 4C are flow charts of a main operation of a camera body
according to the present invention;
FIGS. 5A and 5B are flow charts of a main operation of a sound adaptor
according to the present invention;
FIG. 6 shows a time charts of main operations of a camera body and a sound
adaptor;
FIG. 7 is a diagram showing positional relationships of tracks of a
magnetic disc and a magnetic head in various operations in an AV mode;
and,
FIGS. 8A and 8B are front elevational views of display surfaces of LCD
panels provided in a camera body and a sound adaptor, wherein sound
storage waiting modes are indicated, respectively.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
The invention will be discussed below with reference to FIG. 1 which shows
a block diagram of an internal circuit of a still video camera according
to the present invention. The still video camera has a camera body 100 and
a sound adaptor 200 that is detachably attached to the camera body 100.
The camera body 100 and the sound adaptor 200 are electrically connected
to each other by connectors 1 and 2.
The camera body 100 has a zoom lens 3 driven by a zoom drive circuit 4. An
image of an object to be taken is formed on an image sensor 5 by the zoom
lens 3 and is converted to electrical signals to be outputted as image
pickup signals from an image pickup circuit 6. The image pickup signals
are subject to the necessary treatments, such as the addition of
synchronous signals by an image signal processing circuit 7, to obtain
image signals (video signals). The video signals are inputted to monitor
terminal 8, and an FM modulation circuit 19 through an image/sound
selection switch 9 provided on the camera body 100. The camera body 100
includes a strobe light emitting portion 10, which emits an auxiliary
light upon taking a picture and a strobe light control circuit 11 which
controls the emission of the strobe light.
A magnetic disc 12 is used as a recording medium and is loaded in the
camera body 100 to record image signals and the sound signals. The
magnetic disc 12 is rotated at a constant speed (e.g., 3600 rpm) by a
spindle motor 14 that is controlled by a spindle motor driving circuit 13.
A magnetic head 15 opposed to the magnetic disc 12 is moved in a radial
direction by an actuator (not shown). The magnetic head 15 is moved in the
radial direction until it reaches a predetermined track, which is defined
as one of a plurality of concentric tracks (e.g., 50 tracks) formed
(formated) on the magnetic disc 12 in accordance with the control of a
head driving circuit 16. A PG coil 17 is provided to generate pulses to
detect a fluctuation in the revolutions per second of the magnetic disc
12, thereby keeping the speed constant. The output of the PG coil 17 is
fed back to the spindle motor driving circuit 13 so that the latter
detects a phase difference between the PG pulses generated by the PG coil
17 and a reference pulse, thereby controlling the rotational speed of the
magnetic disc 12.
The magnetic head 15 is connected to either a modulation side, comprising
an FM modulation circuit 19 and an amplifier circuit 20, or a demodulation
side, comprising an FM demodulation circuit 21 and an amplifier circuit 22
depending on the position of a record/play-back selection switch 18a. On
the modulation side, either the image signals or sound signals are
inputted through the image/sound selection switch 9, depending on the
position of the switch, from either the image signal processing circuit 7
or the sound adaptor 200, respectively. The signals inputted through the
selection switch 9 are then FM-modulated and amplified to be fed to the
magnetic head 15. The magnetic head 15 records the FM-modulated image
signals or sound signals on the magnetic disc 12. Conversely, on the
demodulation side, the FM-modulated image signals and sound signals
recorded on the magnetic disc 12 and read by the magnetic head 15 are
amplified and demodulated to be sent to the image signal processing
circuit 7 and the sound adaptor 200, respectively.
The zoom circuit 4, the image pickup circuit 6, the image signal processing
circuit 7, the strobe control circuit 11, the spindle motor driving
circuit 13 and the head driving circuit 16 are controlled by a system
controller 23. To the system controller 23 are connected a monitor
detector 24 which detects whether a monitor (not shown) is connected to
the monitor terminal 8, an adaptor detector 25 which detects whether the
sound adaptor 200 is mounted to the camera body 100, and a notch detector
26 which detects the presence of a write-prevent notch which is used for
preventing the recorded data of the magnetic disc 12 from being erased by
mistake. The outputs of detectors 24, 25 and 26 are inputted to the system
controller 23.
Furthermore, various switches 27, 28, 29, 30, 31, 32, 33, 34, 35, 36a and
36b are connected to the system controller 23, so that when these switches
are turned ON or OFF, appropriate operations are carried out. Battery
switch 27 is turned ON and OFF to supply the system controller with power
and stop the power supply, respectively (a battery which is used to power
the system controller is not shown). Mode switch 28 selects either an
image pickup mode or a recording mode. Selection switch 29 selects a
sub-mode of the selected image pickup mode or recording mode. Up switch 30
and down switch 31 are actuated to increase or decrease the indicated
value, for example, the track number, whereby the magnetic head 15 is
moved. Telephoto switch 32 and the wide angle switch 33 actuate the zoom
drive circuit 4 to perform a power zooming operation in the direction of
the telephoto direction or the wide angle direction, respectively. Strobe
switch 34 sets a light emission mode in which strobe light is emitted, and
EF switch 35 selects an exposure correction mode in which an exposure
correction value is set.
Photometer switch 36a and the image release switch 36b are actuated in
association with image release button 36 provided on the upper surface of
the camera body 100, so that when the image release button 36 is depressed
by a half step or a full step, either the photometer switch 36a or the
image release switch 36b are turned ON, respectively.
The system controller 23 controls the LCD panel 37 provided on the surface
of the camera body 100.
In the sound adaptor 200, the sound received and converted to electrical
signals by a microphone 40 are amplified by amplifier circuit 41 and
subjected to necessary treatments, including restriction of the bandwidth
and removal of the noise, etc., by a sound treatment circuit 42 to form
sound signals. The sound signals to be recorded are inputted to a sound
signal storing portion 43 through a record/play-back selection switch 18b,
which is controlled by a system controller 51. The record/play-back
selection switch 18a of the camera body 100 is controlled by the system
controller 23.
The sound signal storing portion 43 includes an A/D converter circuit 44
which converts the inputted sound signal to digital signals, a RAM 45
which successively memorizes the digital signals, a D/A converter circuit
46 which successively reads the digital signals memorized in the RAM 45
and converts them to analogue signals, and a digital signal processing
circuit (CPU) 47 which controls the operations of the devices or circuits
mentioned above. The A/D converter circuit 44 samples and performs the
quantization of the analogue sound signals inputted thereto and converts
them to digital signals.
The D/A converter circuit 46 successively converts the digital sound
signals read from the RAM 45 into analogue sound signals. The digital
signal processing circuit 47 successively stores the digital sound signals
converted by the sound signal storing portion 43 in the RAM 45 upon
receiving the sound, and successively reads the digital sound signals
stored in the sound signal storing portion 43 in a predetermined
compressed (contracted) time (e.g., about 1/60 second), so that the
digital sound signals are converted to analogue sound signals by the D/A
converter circuit 46, upon recording, respectively. Thus, the time base of
the sound signals of, for example, 5, 10 or 20 seconds are compressed to
about 1/60 second.
Either the sound signals received by the microphone 40 or the FM modulation
signals inputted to the camera body 100 and modulated by sound signal
compressing and reproducing circuit 48 are inputted to the sound signal
storing portion 43, depending on the position of the record/play-back
selection switch 18b. The output of the sound signal storing portion 43 is
sent to a compressed sound recording and processing circuit 49 and a sound
signal processing circuit 50. The sound signals outputted from the
compressed sound recording and processing circuit 49 are inputted to the
camera body 100 and the modulation side (FM modulation circuit 19) through
the image/sound selection switch 9. The sound signals outputted from the
sound signal processing circuit 50 are inputted to the camera body 100 to
be output from the monitor terminal 8. The sound signal compressing and
reproducing circuit 48 performs the necessary operations, such as
deemphasizing of the sound signals with the compressed time base read from
the magnetic disc 12, and the compressed sound recording and processing
circuit 49 performs the necessary operations, such as preemphasizing of
the sound signals with the compressed time base read from the RAM 45.
The digital signal processing circuit 47 of the sound signal storing
portion 43 is controlled by a system controller 51. Various switches 52,
53, 54 and 55 are connected to the system controller 51, so that the
latter can perform the necessary operations when these switches are turned
ON and OFF. When sound receipt starting switch 52 is actuated, sound is
received by the microphone 40 and provisionally stored in the RAM 45.
Sound release switch 53 is actuated to read the sound signals stored in
the RAM 45 and record the same on the magnetic disc 12 of the camera body
100. Sound receipt canceling switch 54 erases the sound signals stored in
the RAM 45. The recording time changing switch 55 switches the sound
compressing mode to change the recording time and can selectively set a 10
second mode or a 20 second mode as in the illustrated embodiment.
The system controller 51 controls the indication of LCD panel 56 that is
provided on the surface of the sound adaptor 200.
FIG. 2 shows the camera body 100 and the sound adaptor 200 as constructed
above. The camera body 100 has a protective cover 60, which protects the
magnetic disc. The magnetic disc 12 can be loaded and unloaded with the
protective cover 60 in place. Numerals 61 and 62 designate an ejection
button which opens the protective cover 60 to load and unload the magnetic
disc and a finder (eyepiece side of finder), respectively.
FIG. 3A shows the indication of the LCD panel 37 provided on the camera
body 100, by way of example. Numeral 70 designates the strobe light
emission mode indicating portion which indicates three modes of automatic
emission. From the left to right these modes are (AUTO), compulsory
emission (ON), and no emission (OFF). Picture taking mode indicating
portion 71 next to the strobe light emission mode indicating portion 70
indicates a single mode, a self-timer mode, a continuous 1-shot mode (one
picture per second), a continuous 2-shot mode (two pictures per second),
and a continuous 5-shot mode (five pictures per second), located in this
order from left to right. The line directly below the picture taking mode
indicating portion 71 is an operation mode indicating portion 72 which
indicates a record mode (REC), a play-back mode (PLAY) and an erasing mode
(ERASE), located in this order from the left. The line directly below the
operation mode indicating portion 72 is a mode indicating portion 73 which
indicates a normal mode (NORMAL) in which only the picture is recorded, an
AV mode (AV) in which both the picture and the sound are recorded, and a
monitor mode (MONITOR) in which only the play-back is effected, located in
this order from left to right.
The line directly below the mode indicating portion 73 is a WB mode
indicating portion 74 which indicates a white balance mode (WB), an auto
mode (AUTO), a cloud balance mode, a fine balance mode, a fluorescent lamp
balance mode, and an incandescent lamp balance mode, located in this order
from left to right.
Below the WB mode indicating portion 74 is provided a calendar indicating
portion 75 which indicates year-month-day and hour-minute-second. A symbol
next to the calendar indicating portion 75 is a magnetic disc indicating
portion 76 which indicates whether the magnetic disc is loaded.
Mathematical symbols and numerals below the light emission indicating
portion 70 form a data indicating portion 78 which indicate the track
number and exposure correction value, etc. A warning indicating portion 79
below the data indicating portion 78 indicates whether the exposure
correction value is set and whether the battery power is sufficient.
FIG. 3B shows an indication of the LCD panel 56 provided on the sound
adaptor 200 by way of example. The uppermost line is an operation mode
indicating portion 80 which indicates a record mode (REC) and a play-back
mode (PLAY). The line below the operation mode indicating portion 80 is a
recording subject indicating portion 81 which indicates that the subject
to be recorded is either sound (AUDIO) or image (VIDEO). A sound recording
time indicating portion 82 located below the recording subject indicating
portion 81 indicates the maximum recording time for which the sound can be
recorded, i.e., a 10 second mode (10) or a 20 second mode (20). Bar codes
located below the sound recording time indicating portion 82 denote a
recording state indicating portion 83. The individual bar codes are
successively lit to indicate the time which has elapsed from the
commencement of a sound recording operation.
FIGS. 8A and 8B show example indications of the LCD panels 37 and 56 in a
waiting mode, according to the present invention. In FIGS. 8A and 8B, the
white portions denote no indication and the black portions denote the
effective indications. The letters surrounded by the black radial lines
mean that the indication light is blinking. For example, "REC" and "AV" in
FIG. 8A, and "AUDIO" in FIG. 8B are illustrated as a blinking light.
The following discussion will be addressed to the normal mode and the AV
mode of the still video camera according to the present invention.
Normal Mode
In this mode, the sound signals and image signals are independently
recorded and reproduced. For instance, when the release button 36 (release
switches 36a and 36b) is turned ON, the image signals are recorded on the
magnetic disc 12. Control signals which are recorded simultaneously with
the image signals, indicate, upon play-back of the track, whether or not
the image signal is recorded independently of the sound signal. In the AV
mode the control signals include data corresponding to both image signals
and the track numbers of the sound signals. The control signals are
subjected to DPSK (Dual Phase Shift Keying) modulation and are
superimposed and recorded on the FM-modulated image signals. The data of
the control signals is controlled by the system controller 23 and is
modulated and demodulated by circuits (not shown), and is decoded by the
system controller 23.
When the sound receiving switch 52 is turned ON, the sound signals are
stored in the RAM 45. Thereafter, when the sound release switch 53 is
turned ON, the sound signals stored in the RAM 45 are recorded on the
magnetic disc 12. An information signal which is recorded simultaneously
with the sound signals indicates whether or not the sound signals are
separately recorded. In the normal mode of the illustrated embodiment, the
sound signals and the image signals can be recorded on optional tracks.
AV Mode
The AV mode is a mode in which the sound signals and the image signals are
recorded and reproduced in association with each other. Namely, the sound
signals and the image signals are recorded on adjacent tracks of the
magnetic disc 12, respectively, and reproduced with a certain relationship
therebetween. Upon recording, the data which represent the sound signals
and the image signals are recorded in the respective data portions.
The main operation of the still video camera is as follows. The main
operation is controlled and carried out by the system controllers 23 and
51. Each of the system controllers 23 and 51 is usually comprised of a
microcomputer and is performed in accordance with a program stored in an
internal ROM of the microcomputer.
Recording and Play-Back at Normal Mode
When the normal mode is selected, the following operation is effected and
controlled by the system controllers 23 and 51.
N1: Recording of Image
When the image release button 36 is depressed to turn the photometering
switch 36a ON, the metering of an object distance, the calculation of the
exposure, and the automatic focus adjustment, etc. are performed.
Furthermore, when the image release button 36 is fully depressed to turn
the image release switch 36b ON, the shutter is opened, so that an object
image is formed on the image sensor 5 by the zoom lens 3. The image pickup
signals converted to electrical signals by the image sensor 5 are recorded
on the magnetic disc 12 as FM modulation signals through the image pickup
circuit 6, the image signal processing circuit 7, the FM modulation
circuit 19, the amplifier circuit 20, the record/play-back selection
switch 18a, and the magnetic head 15.
On the other hand, when the photometer switch 36a is turned ON, the spindle
motor 14 is driven by the spindle motor driving circuit 13 to rotate the
magnetic disc 12 at a constant speed. When the magnetic head 15 is moved
to a predetermined track through the head driving circuit 16, the image
signals for one field are recorded on the associated track by the magnetic
head 15. Upon recording the image signals, the DPSK-modulated information
signals are superimposed and recorded on the FM-modulated image signals of
the same track.
N2: Recording of Sound Signals in the Normal Mode
When the sound receipt starting switch 52 of the sound adaptor 200 is
actuated, the sound signals within a predetermined time (10 or 20 seconds
in the illustrated embodiment) are recorded in the RAM 45. The sound
signals received by the microphone 40 are converted to digital signals and
stored in the RAM 45 through the amplifier 41, the sound signal processing
circuit 42, the record/play-back selection switch 18b, the A/D converter
circuit 44 and the digital signal processing circuit 44.
When the sound release switch 53 is turned ON, the sound release switch
actuating signals (signals for commencing the recording of the sound
signals) are sent to the system controller 23 of the camera body 100 from
the system controller 51, and the digital sound signals, which are stored
in the RAM 45 with a compressed time base, are read out. The digital sound
signals are then converted to analogue signals by the D/A converter
circuit 46 and fed to the camera body 100 through the compressed sound
signal processing circuit 49 and the connectors 1 and 2.
In the camera body 100, the magnetic disc 12 is rotated at a constant speed
by the system controller 23 which receives a start signal of the recording
of the sound signals to move the magnetic head 15 to a predetermined
track. Thereafter, the sound/image selection switch 9 is switched to the
sound side and the record/play-back selection switch 18a is switched to
the record side. The FM-modulation circuit 19 and the amplifier 20, etc.,
stand by to commence the operation. The compressed sound signals inputted
from the connector 1 are fed to the magnetic head 15 through the
image/sound selection switch 9, the FM-modulation circuit 19, the
amplifier 20, and the record/play-back selection switch 18a, and recorded
onto a single track of the magnetic disc 12 as FM-modulation signals. Note
that the above-mentioned control signals are superimposed and recorded on
the sound signals.
N3: Reproduction of Image Signals in the Normal Mode
When a monitor is connected to monitor terminal 8, the connection is
detected by the monitor detector 24.
In response to the detection signal, the system controller 23 enables an
operator to select the play-back mode.
Consequently, when an operator actuates the mode switch 28, the play-back
mode can be selected. In the play-back mode, when the power switch 27 is
turned ON, the magnetic disc 12 is rotated at a constant speed. When the
up-switch 30 and the down-switch 31 are turned ON, the magnetic head 15 is
radially moved to increase or decrease the track number, track by track.
Consequently, when the image release switch 36b is turned ON, the signals
recorded on the associated track are read by the magnetic head 15. The
signals are then demodulated by the FM-demodulation circuit 21 through the
amplifier 22 and outputted from the monitor terminal 8 through the image
signal processing circuit 7. The still picture may be seen if a TV monitor
is connected to the monitor terminal 8.
N4: Reproduction of Sound Signals in the Normal Mode
If the signals read from the magnetic disc 12 are sound signals, the sound
signals are processed in the sound adaptor 200. When the play-back mode is
selected, the play-back mode signals are sent to the system controller 51
from the system controller 23. The system controller 51, which receives
the play-back mode signals, switches the record/play-back selection switch
18b to the play-back side to start the play-back of the sound signals.
The sound signals demodulated by the FM-demodulation circuit 21 are
inputted to the sound adaptor 200 through the connectors 1 and 2, and
converted to the digital sound signals by the A/D converter circuit 44
through the compressed sound reproducing circuit 48 to be stored in the
RAM 45. When the sound signals for a signal track are stored in the RAM
45, the digital sound signals with the initial time base are read from the
RAM 45. Consequently, the digital sound signals are outputted from the
monitor terminal 8 as analogue sound signals through the D/A converter
circuit 46, the sound signal processing circuit 50, and connectors 2 and
1. Accordingly, if a speaker (not shown) is connected to the monitor
terminal 8 through a monitor amplifier, the sound becomes audible.
AV: Record and Play-Back in the AV mode
The operations in the AV mode will be described below with reference to the
flow charts shown in FIGS. 4 and 5.
FIGS. 4 and 5 show the operations of the camera body 100 and the sound
adaptor 200, respectively. In the flow charts, the portions corresponding
to the respective operations discussed below are identified by dotted
lines and corresponding letters (e.g., AV1, AV2, AV3, etc.). The sound
receiving operation is effected in the sound adaptor 200, and the image
pickup operation and the recording of the image and sound signals are
carried out in the camera body 100.
The operations in the camera body 100 and the sound adaptor 200 are
performed by the system controllers 23 and 51 in accordance with programs
stored in internal ROMs thereof.
The necessary data communication is carried out between the system
controllers 23 and 51. For instance, when the image release switch 36b is
turned ON, the image release actuating signal is sent from the system
controller 23 to the system controller 51. When the sound release switch
53 is turned ON, the sound release actuating signal is sent from the
system controller 51 to the system controller 23.
In AV mode, the image signals and sound signals are recorded on adjacent
tracks of the magnetic disc. Note that the single mode is a mode in which
image signals for one field are processed when the image release switch
36b is switched from OFF to ON.
AV1: When Image Release Switch is turned ON after Sound is received by
Microphone
When the sound receipt starting switch 52 is turned ON, sound signals are
received in a predetermined period of time. After the receipt of sound
signals is completed, and when the image release switch 36b is turned ON,
the image signals are recorded on the tracks as image signals. Thereafter,
the received sound signals are recorded on the tracks for the sound
signals adjacent to the tracks on which the image signals have been
recorded.
The timing chart for the above-mentioned operations is shown at AV1 in FIG.
6. In FIG. 6, ".largecircle.--.largecircle." represents the commencement
and completion of the receipt of sound, "V" enclosed in ".quadrature."
represents the recording operation of the image signals, "A" enclosed in
".quadrature." the commencement of the receipt of sound, and
".quadrature." no recording. Furthermore, ".gradient." represents the
releasing of the image signals (when the image release switch 36b is
turned ON), and ".tangle-soliddn." represents the releasing of the sound
signals (when the sound receipt starting switch 52 is turned ON).
When the sound receipt starting switch 52 is turned ON, the sound signals
within a predetermined period of time are stored in the RAM 45, similar to
the operations in the normal mode (steps S201.about.S205, S239, S241,
S243.about.S247, S249). When the sound signals of the predetermined period
of time are stored in the RAM 45, control proceeds to steps S251 and S253.
If switch 53 or switch 36b is turned ON, the stored sound signals are
outputted to the camera body 100 (step S257).
If the image release switch 36b is turned ON in the waiting state, the
system controller 23 checks whether the sound is being stored, or if not,
whether the storage of the sound signals is completed (steps S101, S103,
S119.about.S123). If the sound signals are being stored, receipt of the
sound signals is stopped (i.e., the image release signal is sent to the
sound adaptor 200), and control proceeds to step S125. If the sound signal
is neither being received nor stored in the RAM 45, control is directly
returned to step S101. If the sound signal is not being received and the
storage thereof in the RAM 45 is completed, control proceeds to step S125
(steps S119.about.S123). The check operation mentioned above will be
hereinafter referred to as a "sound receipt check operation."
If the storage of the sound signals is completed, the image signals
picked-up by the zoom lens 3 and the image sensor 5 are recorded on the
image signal track of the magnetic disc 12 (step S125). When recording is
completed, the magnetic head 15 is moved to an adjacent sound signal track
of the magnetic disc 12 (step S127). Thereafter, the sound signals stored
in the RAM 45 are outputted from the sound adaptor 200 to record the same
on the sound signal track of the magnetic disc 12. Thereafter, the
magnetic disc 15 is moved to an adjacent image signal track, and control
is returned to step S101 (steps S127, S129, S131). In the AV mode, upon
recording the sound signals and the image signals, the corresponding sound
signal track number and the corresponding image signal track number are
recorded in the respective code signals, as mentioned above.
AV2: When Sound Release Switch is turned ON after Sound Signals are
received
When the sound release switch 53 is turned ON without turning the image
release switch 36b ON after the sound receipt is completed, the magnetic
head 15 is moved to an adjacent sound signal track of the magnetic disc 12
to record the received sound signals on the sound signal track (see AV2 in
FIG. 6).
This operation will be discussed below with reference to the flow charts
shown in FIGS. 4 and 5.
The sound adaptor 200 outputs the sound signals to the camera body 100 when
the sound release switch 53 is turned ON in the waiting position following
to the completion of the receipt of the sound signals (steps
S251.about.S257).
On the other hand, in the camera body 100, the magnetic head 15 is moved to
the image signal track and control does not proceed until the image
release switch 36b or the sound release switch 53 is turned ON (steps S101
S105). If the sound release switch 53 is turned ON in the waiting
position, the sound receipt is checked (steps S107.about.S111). Here,
since a sound signal is not being received and since the storage of the
sound signals is complete, the magnetic head 15 is moved by one track to
record the sound signals outputted from the sound adaptor 200 onto the
sound signal track (steps S101.about.S107, S111.about.S115). Thereafter,
the magnetic head 15 is moved by one track and control is returned to step
S101 (steps S117, S101.about.S105).
As can be understood from the foregoing, when sound releasing is effected
without effecting image releasing, after the sound signals have been
received, the tracks corresponding to the image signals remain blank. In
other words, the magnetic head jumps the image signal tracks to record on
the sound signal tracks. Accordingly, the image signals can be recorded
later on the blank image signal tracks corresponding to the alternating
sound signal tracks.
AV3: When Image Release Switch is turned ON during Receipt of Sound Signals
When the image release switch 36b is turned ON during the receipt of the
sound signals, the sound receipt is stopped. The image signals are then
recorded on the image signal track and the received sound signals are
recorded on the corresponding sound signal track (see AV4 in FIG. 6).
This operation will be explained below with reference to the flow charts
shown in FIGS. 4 and 5. When the image release switch 36b is turned ON
during the receipt of the sound by the sound adaptor 200, the image pickup
operation and the checking of the sound receipt are carried out (steps
S101.about.S103, S119.about.S123). Here, since the sound is being
received, the sound receipt stop signal is sent to the sound adaptor 200
so that the sound receipt is stopped (steps S119 and S121). The image
signals that have been picked up are then recorded on the image signal
track (step S125). Thereafter, the magnetic head 15 is moved to the
adjacent sound signal track to record the sound signals outputted from the
sound adaptor 200 on the sound signal track (steps S127 and S129). The
magnetic head 15 is then moved to the adjacent image signal track, and
control is returned to step S101 (step S131).
When the sound adaptor 200 receives the image release signal from the
camera body 100 during the receipt of the sound signals, the sound receipt
is stopped (steps S245 and S249). Thereafter, the sound signals received
before the sound receipt is stopped are outputted to the camera body 100
and the control is then returned to step S201 (steps S251 and S257). The
outputted sound signals are recorded on the sound signal track at step
S129 mentioned above.
As can be seen from the above discussion, when the image release switch 36b
is turned ON during the receipt of the sound signals, the sound receipt is
stopped. Accordingly, no noise will occur in the received sound signals
due to the release of the image signals. Furthermore, no voltage drop
takes place, resulting in high quality sound signals.
AV4: When Sound Release Switch is turned ON during Receipt of Sound Signals
When the sound receipt commences without recording image signals and if the
sound release switch 53 is turned ON during the receipt of the sound
signals, the sound receipt is stopped and the sound signals received up
until then are recorded on the adjacent sound signal track by the magnetic
head after having jumped the preceding image signal track (see AV4 in FIG.
6). This operation will be discussed below.
When the sound receipt starting switch 52 in the sound adaptor 200 is
turned ON, the receipt of sound signals commences (steps S201.about.S205,
S239.about.S247). If the sound release switch 53 is turned ON during the
receipt of sound, the sound receipt is stopped and the sound signals
received are outputted to the camera body 100 (steps S247,
S249.about.S257).
The magnetic head 15 is located above the image signal track of the
magnetic disc and waits for the operation of the sound release switch 53
(steps S101.about.105). When the sound release switch 53 is turned ON, the
magnetic head 15 is moved to the corresponding adjacent sound signal track
in accordance with the sound release signal from the sound adaptor 200 to
record the sound signals outputted from the sound adaptor 200 onto the
sound signal track (steps S105, S107, S111 S115). Thereafter, the magnetic
head 15 is moved to the next image signal track and waits for the
operation of the image release switch 36b or the sound release switch 53
(steps S117, S101.about.S105). | | |
