JP2808301B2 - Data signal reproduction device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to still video, and more specifically, to a playback device for a data signal recorded by being multiplexed with a video signal.

"Prior art and its problems" A conventional still video camera photoelectrically converts a subject image with an image sensor, captures a luminance signal (Y) and a color difference signal (C), and combines these signals by FM modulation. It is recorded on a magnetic disk as a multiplexed video signal. Further, according to the recent unified standard of still video cameras, data signals such as field recording, frame recording, and the number of tracks are recorded on a magnetic disk by superimposing them on the video signal by frequency multiplexing.

As a modulation method of this data signal, DPSK (Differen
tial Phase Shift Keying) modulation is employed. Therefore, the data signal is DPSK-modulated and recorded on the magnetic disk so as to overlap with the video signal. At the time of reproduction, a data signal is extracted from a reproduction signal read from a magnetic disk, and the waveform is shaped before DPSK demodulation. Various types of data signal reproducing devices have been developed (for example, Japanese Patent Application Laid-Open No. 62-223855).

However, the conventional data signal reproducing circuit has a complicated circuit configuration and a large scale, which increases the manufacturing cost and complicates the circuit adjustment.

"Object of the Invention" The present invention has been made in view of the problems of the above-described conventional data reproducing apparatus, and has as its object to provide a data reproducing apparatus having a simple circuit configuration.

"Summary of the Invention" The present invention provides a DPSK signal extracted from a multiplexed recording signal,
The purpose of this study was to focus on the fact that the amplitude of the data changes when the state of the data changes, and that a DPSK-modulated data signal and a video signal modulated by another modulation method are multiplex-recorded on the same track. Reading means for reading a multiplexed recording signal from a disc, data signal extracting means for extracting a DPSK-modulated data signal from the multiplexed recording signal read by the reading means, and DPSK-modulated data output from the data signal extracting means Envelope detection means for detecting a signal, change point detection means for detecting a change point of the envelope detected by the envelope detection means, and latch means for inverting and holding an output signal each time the change check means detects a change point And a data signal reproducing device characterized by comprising:

According to the above configuration, the data signal is demodulated by the envelope detection unit and the change point detection unit, so that the circuit configuration is simplified.

Further, by providing latch means for inverting and holding the output signal every time a change point is detected by the change point detection means, each bit of the data signal can be reproduced.

"Examples of the Invention" The present invention will be described below with reference to illustrated examples. FIG. 1 is a block diagram showing a circuit configuration of a still video reproducing apparatus to which the present invention is applied.

As is well known, a video signal composed of a luminance signal and a chrominance signal and a data signal are multiplexed and recorded on the magnetic disk 10. The luminance signal is FM-modulated in a high frequency band and the chrominance signal is FM-modulated in a low frequency band, and the data signal is DPSK-modulated in a frequency band lower than the chrominance signal.

A magnetic disk 10 as a recording medium is rotationally driven by a servomotor 14 controlled by a microcomputer 12.
The multiplex signal recorded on the magnetic disk 10 is read by a magnetic head 16 as reading means. Magnetic head
The track 16 is tracked on a predetermined track by a head tracking mechanism (not shown) controlled by the microcomputer 12.

The multiplex recording signal read by the magnetic head 16 is a preamplifier.
The signal is amplified by 20 and output to a high-pass filter (HPF) 22, a low-pass filter (LPF) 24, and a data signal tuning amplifier 26 as data signal extracting means. The high-pass filter 22 passes only the high-frequency band signal related to the luminance signal, the low-pass filter 24 passes only the low-frequency band signal related to the color signal, and the data signal tuning amplifier 26
Only the DPSK signal relating to the data signal is amplified and passed.

The luminance signal that has passed through the high-pass filter 22 and the color signal that has passed through the low-pass filter 24 are subjected to predetermined processing in a luminance signal processing circuit 28 and a color signal processing circuit 30, respectively, and are output to an encoder 32. The encoder 32 processes the demodulated luminance signal and color signal and outputs the processed signal to the video terminal 34 as a composite video signal.

On the other hand, the data signal tuning amplifier 26 extracts and amplifies only the data signal and outputs it to the envelope detection circuit 36.
The data signal read from the magnetic disk 10 is recorded in synchronization with the horizontal synchronization signal H. 4H from 28H
1 bit of initial bits, 8 bits from 32H, 2 bits of information indicating the distinction between field recording and frame recording, and 28 bits from 40H, 7 bit track number information are recorded synchronously. Have been.

The data signal extracted and amplified by the data signal tuning amplifier 26 is subjected to envelope detection in an envelope detection circuit 36, and the envelope signal is output to a change point detection circuit 38.

The change point detection circuit 38 detects the change point (valley) of the envelope.
Is detected, shaped into a pulse signal, and output to a flip-flop 40 as a latch means.

Flip-flop 40 receives this pulse signal, inverts the output level for each pulse to form a DPSK demodulated data signal, and outputs this to data signal output terminal 42.

FIG. 2 shows a data signal tuning amplifier 26, an envelope detection circuit 36, a change point detection circuit 38, and a flip-flop.
An embodiment of 40 specific circuits is shown.

Multiplexed signal input to the data signal tuning amplifier 26, the DC component by the capacitor C ₁ is removed through the transistor Tr _1, the second stage of the parallel resonant circuit connected to the collector of the transistor Tr ₂ LC ₁ and emitter by the connected series resonant circuit LC _2, only the data signal (DPSK signal) is amplified. Then, the DC component by the capacitor C ₃ is removed, and further the band amplified by the transistor Tr ₃ of the parallel resonance circuit LC ₃ to the collector are connected, and output to an envelope detection circuit 36. The output waveform of the data signal tuning amplifier 26 is shown in FIG.

The data signal input to the envelope detection circuit 36 is
Envelope detection is performed by transistors Tr ₄ and Tr ₅ whose emitters are grounded via a capacitor C ₄ , and a change point detection circuit 38
Is output to The output waveform of the envelope detection circuit 36 is as shown in FIG. That is, the portion where the carrier represents the same data signal bit has a constant potential because the amplitude is constant, but the portion where the frequency of the carrier changes, that is, the boundary where the data signal bit is inverted, has a "V" shape. It becomes a potential that has changed in the shape.

The enveloped data signal at the changing point detection circuit 38, the DC component is removed by the capacitor C _5, is amplified by the transistor Tr ₆ are placed in the input of the monostable multivibrator (MM) 39 in. Since the monostable multivibrator 39 outputs an “H” pulse every time the input rises, the data signal is a pulse signal wave whose “V” portion is shaped into a square wave as shown in FIG. Becomes The data signal thus shaped is output to flip-flop 40.

The flip-flop 40 comprises a D flip-flop 41, and the above-mentioned enveloped pulse signal is input to the CL input. The output of the D flip-flop 41 is fed back to the input D, and the output Q is output to the data signal output terminal 42. Therefore, each time an "H" pulse is input to the input CL, the level of the output Q is inverted and latched at that level, resulting in the waveform (D1) or (D2) shown in FIG.

Data signal output terminal 42, that is, D flip-flop 41
Is output to the microcomputer 12 in a bit unit through a logic circuit, for example, an exclusive OR gate 44 which takes an exclusive OR of a pair of inputs shown in FIG. 3A. One input of the exclusive OR gate 44 is a flip-flop
The Q output of 40 is input, and the other input is the output of the exclusive OR gate 44, which is output by the microcomputer 12 at a predetermined timing based on the horizontal synchronization signal, a predetermined time ago (for 4H of the horizontal synchronization signal). , Exclusive OR at this time
The data signal is reproduced bit by bit by the output of the gate 44.

The output signal of the exclusive OR gate 44 when the Q output is input to the other input is decoded by the microcomputer 12 as a reproduction data signal, stored in the memory 12 and subjected to predetermined processing. In this embodiment, the field / frame information bit is "10" and the track number bit is "01101 (0
1) ”, it is decoded as the 35th track outside the frame record, and the track number is displayed as“ 35 ”on a predetermined display.

Note that, without providing the exclusive OR gate 12, the 3B
As shown in the drawing, a configuration in which exclusive or processing is performed in the microcomputer 12 may be employed.

According to the present embodiment, since the change of the data signal bit can be detected and demodulated by the envelope detection circuit and the change point detection circuit of the carrier of the data signal, the configuration of the data signal reproduction circuit is simplified.

Although the present invention has been described based on the illustrated embodiment, the present invention is not limited to this embodiment. In short, the present invention has a circuit configuration capable of detecting an envelope of a modulated data signal and detecting a change point of the envelope. I just need it.

Further, the data reproducing apparatus of the present invention can be applied to a still video camera including the reproducing apparatus.

[Effects of the Invention] As is clear from the above description, the data signal reproducing apparatus of the present invention can demodulate a data signal by envelope-detecting a carrier of a DPSK-modulated data signal and detecting a change point thereof. The configuration is simplified, and the circuit can be made compact and the cost can be reduced.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an outline of a still video reproducing apparatus to which the data signal reproducing apparatus of the present invention is applied, and FIG. 2 is a data signal tuning amplifier, an envelope detecting circuit, a change point detecting circuit and FIGS. 3A and 3B are more specific circuit diagrams of the flip-flop, FIGS. 3A and 3B are circuit diagrams each showing a portion for inputting a demodulated data signal to a microcomputer, and FIG. 4 is a timing chart of each circuit of the embodiment. . 10 ... magnetic disk (recording medium), 12 ... microcomputer, 26
………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………………… ned…
Flip-flop, 41 ... D flip-flop, 44 ...
Exclusive OR gate.

Claims (5)

(57) [Claims] 1. A reading means for reading a multiplexed recording signal from a magnetic disk in which a DPSK-modulated data signal and a video signal modulated by another modulation method are multiplex-recorded on the same track, and the reading means reads the multiplexed recording signal. A data signal extracting means for extracting a DPSK modulated data signal from the multiplexed recording signal; an envelope detecting means for detecting the DPSK modulated data signal output from the data signal extracting means; and an envelope detecting means for detecting the DPSK modulated data signal. A data signal reproducing apparatus comprising: a change point detecting means for detecting a change point of an envelope; and a latch means for inverting and holding an output signal every time the change check means detects a change point. 2. A data signal reproducing apparatus according to claim 1, wherein said data signal extracting means comprises a data signal tuning amplifier. 3. The data signal reproducing device according to claim 1, wherein said latch means is constituted by a flip-flop circuit. 4. A data signal reproducing apparatus according to claim 1, wherein said latch means outputs a signal whose level is inverted each time said change point detecting means detects a change point, and a pair of input signals. And a control unit to which an output signal of the flip-flop is input. An output signal of the flip-flop is input to one input of the logic circuit, and the other input is input to the other input of the logic circuit. Receiving an output signal of the flip-flop delayed by a predetermined time by the control means, and decoding the DPSK-modulated data signal based on an output of the logic circuit at this time. Signal playback device. 5. The data signal reproducing apparatus according to claim 1, wherein said recording medium is a magnetic disk.