DE4009952A1 - DATA SIGNAL PLAYER - Google Patents

Abstract

A data signal reproducing apparatus comprises an envelope detecting means 36 for detecting a DPSK-modulated data signal outputted from data signal extracting means 26, a change point detecting means 38 for detecting a point of change of the detected envelope, and a latch means 40 for inverting and holding the output signal every time said change point detecting means detects a point of change of said envelope. The invention is also directed to an electronic still camera having a read means 16 for reading a picture signal and a DPSK-modulated data signal which have been recorded on a recording medium in the form of a multiplex recording signal and a data signal extracting means for extracting the DPSK- modulated data signal 42 from the multiplex recording signal read by said read means. <IMAGE>

Description

The present invention relates to single frame video device and in particular a device for playback or reproduction or recovery of a data signal, which together with an image signal in the form of a multiplexed recording signal is recorded.

A typical conventional single-frame video camera has heretofore been designed such that the image of an object is photoelectrically converted by an image scanner to capture an object image in the form of a luminance signal ( Y ) and a color signal ( C ), and these signals are mutually frequency-modulated combined or linked and recorded on a magnetic disk in the form of a multiplexed image signal or multiplexed image signal. According to a recently unified standard for still video cameras, a data signal indicating whether a particular record is a field record or a frame record and which also bears other information such as the order number of a track on which a particular record has been stored , recorded on a magnetic disc, being superimposed on the above-described image signal by a frequency division multiplexing method.

In order to modulate the data signal, a DPSK (Diff rential phase shift encryption) modulation related. Accordingly, the data signal of a DPSK Exposed to modulation and placed on a magnetic disk records, being superimposed on the image signal. Around to reproduce the recorded data will Data signal from the frequency-modulated signal extra which is read from the magnetic disk, and DPSK demodulation after waveform shaping exposed. There are various devices for reproduction data signal have been developed (e.g. the Japanese German Patent Application Laid-Open (KOKAI) No. 62-2 23 855 (1987)).

The conventional circuit for reproducing the data signals, however, has a complicated circuit structure and the area or the scaling or the dimension the circuit is great. Accordingly, the production cost Most high and the circuit control is complicated or expensive.

With regard to the problems described in the conventional data reproducing device, it is one Object of the present invention to reproduce data device with a simplified circuit structure  to accomplish.

To achieve this aim, the device according to the present invention that was made by noticing was that the DPSK carrier signal is in phase returns when the state of the non-carrier signal reverses or changes an envelope detection direction for detecting or detecting a DPSK module gated data signal, a reversal point detection direction for detecting a reversal point of the detected Envelope and a buffer device for the In vertical and hold the output signal always if the reversal point detection means a reversal point of the envelope detected.

Through the arrangement described above, the data signal by the envelope detection device and the reversal point detection device demodulates and the circuit structure is therefore simplified.

It is also possible to add every bit of the data signal reproduce by using a cache device is provided that the output signal always in vertizes and stops when the reversal point detection is on direction detected a reversal point of the envelope.

According to a further aspect, it is advantageous of the present invention for reading an image signal and a DPSK modulator th data signal recorded on a recording medium in the form of a multiplexed recording signal have been drawn, a data signal extraction direction to extract the DPSK-modulated data  signals from the ge read by the reading device multiplexed recording signal, the extracted Data signal of the envelope detection device supplied leads.

Further advantages, features and possible applications The present invention results from the following ing description of exemplary embodiments in Verbin with the drawing, whereby

Fig. 1 is a block diagram schematically showing a still image video reproducing apparatus in which the data signal reproducing apparatus of the present invention is applied;

Fig. 2 is a diagram showing the circuits of a matched to the data signal amplifier, the envelope detection circuit, the reversal point detection circuit and a flip-flop in greater accuracy, which are present in the embodiment shown in Fig. 1;

. 3A and 3B are circuit diagrams Fig each showing a section, wherein the profiled data signal demodu eingege the microcomputer is ben; and

Fig. 4 is a timing diagram showing the waveforms of various circuits of this embodiment.

The present invention is described below with reference to an embodiment illustrated in the drawing. Fig. 1 is a block diagram showing the circuit construction of an apparatus for reproducing or reproducing still images to which the present invention is applied.

On a magnetic disk 10 - as is generally known - an image signal, which contains a luminance signal and a chrominance (color) signal, is recorded together with a data signal, in the form of a multiplexed recording signal. The luminance signal and the chrominance signal are frequency-modulated in a high and a low frequency band and the data signal is DPSK-modulated in a frequency band which is lower than that for the chrominance signal.

The magnetic disk 10 , which serves as a recording medium, is driven for rotation by a servo motor 14 which is controlled by a microcomputer 12 . The multiplex signal recorded on the magnetic disk 10 is read by a magnetic head 16 which serves as a reading device. It should be noted that the magnetic head 16 is moved to follow a predetermined track by the action of a head tracking mechanism (not shown) which is controlled by the microcomputer 12 .

The recorded multiplex signal, which is read by the magnetic head 16 , is amplified in a preamplifier 20 and then a high-pass filter (HPF) 22 , a low-pass filter (LPF) 24 and a data signal-matched amplifier 26 , which acts as a data signal extraction device serves. The high-pass filter 22 passes only the signals in the high frequency band which relate to the luminance signal, while the low-pass filter 24 only passes the signals in the lower frequency band which relate to the chrominance signal, and the amplifier 26 tuned to the data signal amplifies and leaves only the data signal carrier signal through.

The luminance signal passed through the high-pass filter 22 is subjected to predetermined processing in a luminance signal processing circuit 28 and then supplied to an encoder 32 . Similarly, the chrominance signal passed through the low pass filter 24 is subjected to predetermined processing in a chrominance signal processing circuit 30 and then supplied to the encoder 32 . The encoder 32 demodulates the frequency-modulated luminance or chrominance signal and outputs it to a video connection 34 in the form of a composite image signal (video signal).

In the meantime, the amplifier 26, which is tuned to the data signal, only extracts and amplifies the data signal and outputs it to an envelope detection circuit 36 . It should be noted that the data signal read out from the magnetic disk 10 is synchronous with the horizontal synchronizing signal H. In particular, the following pieces of information have been recorded synchronously (see Fig. 4): a start bit to which 4H is assigned from 28H to 32H; 2-bit information indicating whether a particular record is a field record or a frame record and is assigned to 8H from 32H to 40H; and 7-bit track number information assigned to 28H from 40H to 68H.

The data signal extracted and amplified in the amplifier 26 matched to the data signal is subjected to envelope detection in the envelope detection circuit 36 , and the envelope signal is output to a reversal point detection circuit 38 .

The reversal point detection circuit 38 detects a point (valley) of the reversal of the envelope, forms it into a pulse signal and outputs it to a flip-flop 40 , which serves as a buffer device.

Each time the flip-flop 40 receives the pulse signal em, it inverts its output level to form a DPSK demodulated data signal and outputs it to a data signal output terminal 42 .

FIG. 2 shows an example of specific circuit configurations of the amplifier 26 matched to the data signal, the envelope detection circuit 36 , the reversal point detection circuit 38 and the flip-flop 40 .

The multiplex signal input to the amplifier 26 matched to the data signal is passed through a capacitor C 1 , in which the DC components are removed, and then leads to a base of a transistor Tr 1 . Thereafter, only the data signal is (DPSK carrier signal) in a parallel resonance circuit LC 1 ver-reinforced, with the collector of a second stage Tran sistors Tr 2 is connected, and circuitry in a series resonant LC 2 reinforced with the emitter of the transi stors Tr 2 is connected. After the DC component in a capacitor C 3 has been removed, the data signal is subjected to a band-limited amplification by a transistor Tr 3 with a parallel resonance circuit LC 3 which is connected to its collector, and then leads to the envelope detection circuit 36 .

Fig. 4 (A) shows the output waveform of the tuned amplifier 26 to the data signal. The data signal input to the envelope detection circuit 36 is subjected to envelope detection by transistors Tr 4 and Tr 5 , the emitter of the transistor Tr 4 being connected to ground via a capacitor C 4 , and then supplied to the reversal point detection circuit 38 . Fig. 4 (B) shows the output waveform of the detection circuit 36 Hüllkur ven. Considered in detail, a section of the carrier signal which represents the same data signal bit has a fixed amplitude and therefore shows a fixed potential, whereas a section of the carrier signal in which the frequency changes, ie a border section in which the data signal bit is inverted, shows a potential that changes according to the shape of a V.

Once the reversing point detecting circuit, the DC component has been removed ent 38 by a capacitor C 5, the envelope data signal by a Transister Tr 6 is amplified and then input to a monostable multivibrator len (MM). 39 Since the monostable multivibrator 39 outputs an "H" pulse each time the input signal has a rising edge, the data signal is shaped into a pulse signal, with each V-section being transformed into a rectangular waveform as shown in FIG. 4 (C) is shown. The data signal thus shaped is output to the flip-flop 40 .

The flip-flop 40 comprises a D-flip-flop 41 , in which the envelope pulse signal described above is input to the input CL . The output Q of the D flip-flop 41 is fed back to the input D during the off gear Q on the data signal output terminal is discharged 42nd Accordingly, each time an "H" pulse is input to the CL input, the level of the Q output is inverted and the Q output is latched to the inverted level, resulting in that in FIG. 4 (D1) or Fig. 4 (D2) leads waveform.

The output from the data signal output terminal 42 , ie the output Q of the D flip-flop 41 is bit by bit from the microcomputer 12 via a logic circuit, which can be, for example, an exclusive-OR gate 44 , which is shown in FIG. 3A is shown. One input terminal of the exclusive-OR gate 44 is connected to the output Q of the flip-flop 40 , while the other input terminal of the gate 44 is connected to the output Q of the exclusive-OR gate 44 a predetermined time before (corresponding to 4H of the horizontal synchronizing signal) is supplied, which is output from the microcomputer 12 at a predetermined time based on the horizontal synchronous signal, whereby the data signal is reproduced on a bit-by-bit basis.

The reproduced data signal, which is output from the exclusive-OR gate 44 , is decoded in the microcomputer 12 and stored therein, as well as subjected to predetermined processing. In this embodiment, the field / frame information bits are "10" and the track number bits are "01101 (01)", and the data signal is therefore decoded as one frame recorded on the outer 35th track. Then the track number "35" is shown on a given display.

It should be noted that the arrangement may be such that the exclusive-or gate 44 is not provided, but the execution of the exclusive-or function is instead carried out in the microcomputer 12 as shown in Fig. 3B.

In the previously described embodiment, it is possible the data signal by detecting changes or reversals of the data signal bits using the data signal carrier envelope detection circuit and the demodulation point detection circuit. Accordingly, the arrangement or structure of the data signal playback circuit simplified.

Although the present invention by the in the drawing Embodiments explained have been described , it should be noted that the present invention not necessarily to the execution described is limited, and that it is rather essential is to create a circuit structure that a Envelope detection of a modulated data signal and a detection of a reversal point of the envelope possible, which results from the envelope detection.

Furthermore, the data reproduction according to the invention can  direction also applied to single-frame video cameras that have equipment for playback gene.

From the preceding description it follows that the data signal reproducing apparatus of the present Invention is capable of enveloping the data signal curve detection of the carrier signal of the DPSK modulator th data signal and by detecting a reversal point to demodulate the detected envelope. It is therefore possible to simplify the circuit structure, and thus reduce the size of the circuit and the Pro reduce production costs.

Claims (8)

1. Data signal playback device, characterized by

• - an envelope detection device ( 36 ) for detecting a DPSK-modulated data signal;
• - a reversal point detection device ( 38 ) for detecting a reversal point of the detected envelope; and
• - An intermediate storage device ( 40 ) for inverting and holding the output signal whenever the reversal point detection device detects a reversal point of the envelope.

2. Device according to claim 1, characterized by a reading device ( 16 ) for reading the DPSK-modulated data signal which has been recorded on a recording medium ( 10 ), the read DPSK-modulated data signal being supplied to the envelope detection device ( 38 ) . 3. Apparatus according to claim 1, characterized by a reading device ( 16 ) for reading an image signal and a DPSK-modulated data signal, which have been recorded on a recording medium ( 10 ) in the form of a multiplex recording signal, a data signal extraction device ( 26 ) for extracting the DPSK-modulated data signal from the multiplex recording signal which is read by the reading device ( 16 ), the DPSK-modulated data signal being supplied to the envelope detection device ( 36 ). 4. Device according to one of claims 1 to 3, characterized in that the reversal point detection device ( 38 ) contains a monostable multivibrator ( 39 ) which outputs a pulse when a phase of the envelope reverses. 5. The device according to claim 4, characterized in that the buffer device ( 40 ) contains a flip-flop circuit ( 41 ) which inverts and holds an output signal when the monostable multivibrator ( 39 ) outputs the pulse. 6. Device according to one of claims 1 to 5, characterized in that the recording medium is a magnetic disk ( 10 ). 7. Device according to one of claims 2 to 6, characterized in that the reading device is a magnetic head ( 16 ). 8. The device according to claim 3, characterized in that the data signal extraction device is a matched to the data signal amplifier ( 26 ).