JPS63316582A - Magnetic recorder for slow photographing - Google Patents

Abstract

PURPOSE:To attain the recording of slow photographing by adding an image number to a video signal, storing the added video signal, rewinding a video tape, redriving the tape, and when the tape reaches a prescribed position, reading out the stored contents to record the contents in the video tape. CONSTITUTION:When slow photographing recording is commanded by an operation part 28, switching circuits 4, 26 are switched to the recording side by a signal outputted from a system control circuit 27 and an image number is added to a video signal outputted from a video camera 1 by an encoder 2a, the added signal is stored in a memory 2b and the stored signal is recorded on the video tape 15 only by one frame. After recording one frame, the tape is turned to a reproducing mode, the set number N of control signals is detected by a control head 18 to stop the tape. After waiting a prescribed time, the tape 15 is driven in the forward direction, the succeeding recording position is commanded on the basis of the image number and a video signal for one frame is read out from a memory 2b and recorded on the tape 15. Similar one-frame recording is repeated to attain slow photographing recording.

Description

[Detailed Description of the Invention] "Industrial Application Field" The present invention relates to a time-lapse magnetic recording device for photographing slow phenomena such as the movement of clouds and the progress of flowering and magnetically recording them on videotape. .

``Prior art'' Conventionally, in order to take and record images at ultra-low speeds, the tape feed speed was reduced to an ultra-low speed, such as in a two-cooked machine, and recorded intermittently on a Hob 30D, as in the case of time-lapse VTRs. The method was adopted.

"Problem to be solved by the invention" As in the past, the recording speed is -U of the standard playback speed.
In this case, the speed of the tape and the speed of the cylinder for video JO6300 cannot be accurately controlled, and the recording track angle of the image signal becomes inaccurate, and the video head cannot trace accurately during playback at standard speed, resulting in noise. There was a problem that occurred. Further, although special VTR machines for ultra-low-speed photography and recording exist, there is a problem in that they are not compatible with standard VTR machines or general-purpose VTR machines.

Means for Solving Problems The present invention was made to solve the above-mentioned problems, and it modulates a video signal with a modulation circuit, and records this modulation signal on a video tape with a video head. , a device which reproduces a video signal by demodulating the recorded signal with a demodulation circuit, comprising: a servo circuit for controlling scanning of the video head and driving of the video tape; and a servo circuit for controlling scanning of the video head and driving of the video tape, and An operating unit to be operated, a switching circuit that switches the signal path to the video head depending on the recording mode and correction mode, an encoder that adds an image number to the recording video signal of the input video signal at predetermined intervals, and an encoder that adds an image number to the recording video signal of the input video signal. The system control circuit comprises a memory for storing at least one screen of converted images, a decoder circuit for separating the image number from the reproduced video signal, and a system control circuit for mutually controlling these circuits. After numbering and recording images of arbitrary frames,
rewinding the videotape by a predetermined amount, storing the number of control signals corresponding to the rewinding in the RAM, and calculating the waiting time by the CPU according to the slow speed conditions input to the operation section;
After this waiting time has elapsed, the video tape is driven to command the next recording position based on the picture number, and a command is given to read out the video signal of the corresponding picture number from the memory and record it on the tape. It is characterized by this.

"Operation" A frame number corresponding to one frame of image is added by an encoder and recorded in memory. On the other hand, the tape is rewound until the number of control signals reaches a certain number (specifically, for example, 30). Then, the tape is stopped or paused at this position.

When a start signal for photographing and recording is input after a certain period of time, writing of the next frame to the memory is stopped, a playback mode is entered, and the tape is transported in the forward direction at a standard speed. A frame signal is extracted from the reproduced video signal, and based on this frame number, the original recording position is detected, and when it returns to that position, the moving speed has reached a stable state. When the tape moves one frame further from the original recording position, the recorded image signal is read out from the memory, and one frame of the video signal is photographed and recorded on the videotape with a frame number added thereto. Thereafter, the same operation is repeated to record images. When a tape photographed and recorded in this manner is operated in a standard speed playback mode, images are played back at high speed.

"Example" Hereinafter, one embodiment of the present invention will be described based on the drawings.

(1) is a TV camera, and this TV camera (1) includes an encoder (2a) that adds a continuous image number such as a frame number to each frame, and at least one frame encoded by this encoder (2a). A memory (2b) for recording video signals for 20 minutes, an FM modulation circuit (2) for video signals,
It is coupled to the recording side contact (5) of the first switching circuit (4) via the amplifier circuit (3). This first switching circuit (4
) is connected to a video signal output terminal (9) via an amplifier circuit (7) and a video signal demodulation circuit (8).
and a decoder (10) for extracting the picture number from the video signal.

A common contact (11) of said first switching circuit (4) is coupled to a video head (not shown) in a rotating head drum (12). The outer periphery of this rotary head drum (12) has a movable tape guide (13) (14) at a predetermined angle.
) is wound around the video tape (15), and this video tape (15) is run by a capstan (17) provided on a capstan drive wheel (16). (18) is a control head that detects a control signal (20) formed on a control track (19) of a video tape (15).

A servo circuit (22) for controlling these drives is coupled to the rotating cylinder (21) for driving the video head in the rotating head drum (12) and the capstan (17) for driving the video tape. A second switching circuit (26) is coupled to the circuit (22) to switch the signal from the control head (18) to a recording side contact (24) and a reproduction side contact (25) via a common contact (23). has been done.

The servo circuit (22) is coupled to a system control circuit (27) that controls the entire system, and the system control circuit (27) also has an operation section (28) for controlling the standard speed operation mode, time-lapse recording mode, etc. are combined, and the encoder (2a) and the memory (
2b), a decoder (10), a first . Second switching circuit (4
)(26) are combined.

As shown in FIG. 2, the system control circuit (27) includes a CPU (29), a ROM (30), and a RAM (3).
1), which are connected via an input/output circuit (32) to the operating section (28), servo circuit (22), and encoder (
2a), memory (2b), decoder (lO), signal process system control circuit (33), mechanical system control circuit (34)
is combined with

The operation of the above configuration will be explained based on the flowchart of FIG. 4.

(1) When time-lapse photography recording is commanded using the operation unit (28), a signal from the system control circuit (27) causes the first
, the second switching circuit (4) (26) is the recording side contact (5)
(24), the rotary cylinder (21) moves the video head onto the video track (35) of the video tape (15), and the capstan (17) moves the video head onto the video track (35) of the video tape (15).
) to run the videotape (15) at a standard constant speed.

Then, the encoder (2a) adds an image number to the video signal from the video camera (1). The position to be added is, for example, during the vertical retrace line after the vertical synchronization signal.

Input consecutive frame numbers as image numbers.

Note that the frame numbers are not limited to consecutive numbers.

The video signal for one screen with the image number added in this way is recorded in the memory (2b). The signal recorded in this memory (2b) is sent to the video head via the video modulation circuit (2) and the amplifier circuit (3), and only one frame is recorded at the frame number (MO) position of the video tape (15). do.

(2) When one frame is recorded, the videotape (15) enters the playback mode, moves in the rewinding direction by a preset number of control signals (N), and enters a stopped or paused state. That is, the number (N) of the rewound control signals is detected by the control head (18) and stored in the RAM (31) of the system control circuit (27) via the second switching circuit (26). .

This number (N) is the time it takes to rise to the set standard speed when it approaches the original frame number (M,) that has already been recorded when switching back to recording mode. For example, N =
Set it to 30.

(3) The camera waits at the rewound position until the start of the next photographic recording, but the waiting time, that is, the timing of the next start, is determined as follows.

Number of frames not recorded due to input time-lapse shooting conditions (X)
seek. This X becomes 99 when the set slow speed is set as standard □. Therefore, waiting time M=M, +X
-N.

(4) If this M=Mo×X−N holds true, the memory (2
In b), the writing of the next frame is stopped, the playback mode is entered, the videotape (15) starts moving in the forward direction, and the number of previously stored control signals (N) is
When becomes O, the videotape (15) becomes the original M. However, there is an additional delay of one frame number. In other words, M. The videotape (15) moves by +1. Then, the video signal for one frame is read out from the memory (2b) and recorded on the videotape (15).

(5) After that, when one frame is recorded in the same way, it is rewound to a predetermined position and waits for the slow speed condition time, during which it is recorded in the memory (2b), and when the start time comes, the videotape (15) is run in the forward direction. Then, the operation of reading data from the memory (2b) and recording the video signal at a position further traveled by one distance from the previous recording position is repeated.

Next, the videotape recorded as in step 1 or more (1
If you play 5) at standard speed, the image will be displayed at super high speed.

In the above embodiment, one shooting record is one frame, but
It may be several frames. Furthermore, the slow speed conditions are not constant and can be changed midway.

"Effects of the Invention" As described above, the present invention temporarily stores a video signal in a memory,
This is configured so that when the videotape reaches a predetermined position, it is read out from memory and recorded on the videotape, so the speed of the video head and videotape during recording is standard speed, and the recording position is extremely accurate. The recording track angle of the image signal will not become inaccurate, and therefore signal deviations on the videotape during splicing can be corrected.
During playback, the video head can be traced accurately and there is no noise. Further, it has excellent effects such as being able to employ ultra-low-speed photography and recording even in standard VTR machines and general-purpose VTR machines.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing an embodiment of a time-lapse magnetic recording device according to the present invention, FIG. 2 is a block diagram of a system control circuit in FIG. 1, FIG. 3 is an explanatory diagram of a videotape, and FIG. It is a flowchart. (1)...TV camera, (2a)...encoder,
(2b)...Memory, (2)...Modulation circuit, (3)
(7)...Amplification circuit, (4)...First switching circuit, (5)...Recording side contact, (6)...Reproducing side contact,
(8)...Demodulation circuit, (9)...Video signal output terminal, (10)...Frame data decoder, (11)
... Common contact, (12) ... Rotating head drum, (
13) (14)...Movable tape guide, (15) Video tape, (16)...Capstan drive wheel, (17)...Capstan, (18)...Control head, (19) ... Control track, (20) ... Control signal, (21) ... Rotating cylinder, (22) ... Servo circuit, (23) ...
・Common contact, (24)...recording side contact, (25)...
・Reproduction side contact, (26)...second switching circuit, (2
7)...System control circuit, (28)...
Operation unit, (29)...CPU, (30)...ROM
, (31)...RAM, (32)...input/output circuit,
(33)...Signal process system control circuit, (34)...
- Mechanical control circuit, (35)...video track. Applicant Fujitsu General Co., Ltd. Procedural Amendment (Method) Commissioner of the Patent Office Kunio Ogawa 1, Indication of the case Patent Application No. 152453 of 1988 2, Name of the invention Time-lapse magnetic recording device 3, Person making the amendment Case Relationship with Patent applicant address 1116 Suenaga, Takatsu-ku, Yozaki City, Kanagawa Prefecture
Name (661) Fujitsu General Co., Ltd. Representative Shibe Yoshikawa 4, Agent Address: 102 6, Drawing subject to amendment 7, Contents of amendment - ~ elle/

Claims (2)

[Claims] (1) In an apparatus in which a video signal is modulated by a modulation circuit, this modulated signal is recorded on a video tape by a video head, and the recorded signal is demodulated by a demodulation circuit to reproduce the video signal, the video head a servo circuit that controls the scanning of the video tape and the driving of the video tape; an operating section that operates according to the standard speed and slow speed modes; and a switching circuit that switches the signal path to the video head depending on the recording mode and the correction mode. An encoder that adds image numbers to the recorded video signal of the input video signal at predetermined intervals, a memory that stores at least one screen worth of images encoded by this encoder, and a decoder circuit that separates the image number from the reproduced video signal. and a system control circuit that mutually controls these circuits, and this system control circuit rewinds the videotape by a predetermined amount after recording the image of an arbitrary frame by numbering it. The number of control signals obtained is stored in the RAM, and the CPU calculates the waiting time based on the slow speed conditions input to the operation section. After the waiting time has elapsed, the videotape is driven and the next recording position is determined based on the image number. 1. A time-lapse magnetic recording apparatus, characterized in that the time-lapse magnetic recording apparatus is configured to issue a command to read a video signal of a corresponding image number from the memory and record it on a tape. (2) The time-lapse magnetic recording device according to claim 1, wherein consecutive frame numbers are added as image numbers.