Abstract:
A system for information recording and regenerating wherein a regeneration mode control signal is included in the horizontal scan of each frame of a video signal recorded on a video disk. The control signal includes a series of frame signal components and two field signal components associated with each frame signal component. The signal values of the frame and field signal components determine whether all or only selected video disk operations can be performed.

Description:
FIELD OF THE INVENTION 
     This invention relates to an information recording and regenerating system and more particularly to an information recording and regenerating system which contemplates automatically detecting the regenerative operation mode of a device for regenerating a video format signal recorded on a recording disk. 
     BACKGROUND OF THE INVENTION 
     A so-called SWS (Still With Sound) method has been proposed which comprises the steps necessary to record, on a recording disk, control information in addition to audio information digitized together with video information, and to regenerate at the time of the regenerative operation the audio information according to the control information. Thus, sound may be added to corresponding still image information. In this method, an adaptor has been developed in order that an ordinary VDP (video disk player) can be additionally provided with an SWS processor which regenerates and processes the audio information and the control data (hereinafter referred to as SWS data). 
     Since the SWS processor may properly read the SWS data if the VDP is in the normal regenerative mode, forward-framing regenerative mode, still image regenerative mode, or the like, it is sufficient for the SWS processor to carry out signal processing according to the content of properly read data. However, the SWS processor is not able to read the SWS data properly when the VDP is in certain specific regenerative modes such as reverse regenerative mode, fast-forward regenerative mode, or the like. Therefore, data must not be sent to the control circuit during any of the latter specific regenerative modes. Accordingly, a circuit configuration is required which enables the SWS processor to automatically discriminate the current VDP operation mode. 
     OBJECTS AND SUMMARY OF THE INVENTION 
     The present invention achieved in view of these requests, aims to provide a recorded information regenerating system to enable the automatic discrimination of the VDP regenerative operation mode according to a regenerative signal read by and received from the VDP. 
     Another object of the present invention is to enable implementation of the SWS mode in a manner not hindered by operation in a specific regenerative mode. 
     The recorded information regenerating system according to the present invention comprises the method and apparatus for recording on a recording medium a video format signal including frame discriminate code data that are different from each other in adjacent frames and field discriminate code data that correspond to the fields included in each frame and for discriminating the regenerative operation mode at the time of the regeneration according to the contents of the frame and field discriminate code data. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The manner by which these and other objects, features, and advantages of the present invention are achieved, as well as the invention itself, will become more apparent from the following detailed description when considered in view of the accompanying drawings, wherein: 
     FIG. 1 illustrates a video format signal including frame discriminate code data and field discriminate code data recorded on a recording disk processed by the method of the present invention; 
     FIG. 2 is a circuit block diagram of an embodiment of a circuit for processing the video format signal of FIG. 1; and 
     FIGS. 3(a)-3(j) are waveform diagrams of signals generated by the elements of the circuit of FIG. 1. 
    
    
     DETAILED DESCRIPTION 
     FIG. 1 shows an example of a video control signal including frame discriminate code data and the field discriminate code data to be recorded on a recording disk according to the present invention. Each of these codes is a 1-bit data element which is inserted and recorded in the specific horizontal scanning duration of each field of the video format signal. The frame discriminate code data are recorded so that the code values are different from each other in adjacent frames and the field discriminate code data are recorded so that the code values in the first field and the second field are different from each other. 
     FIG. 2 shows an embodiment of the regenerative system in the case of the discrimination of the VDP regenerative operation mode using the code information shown in FIG. 1. A code read circuit 1 reads the frame discriminate code data and the field discriminate code data from the regenerated output of the VDP and holds these data until the next field discriminate code data is read. A timing signal generating circuit 2 generates two trains (c and i) of cyclic pulses for each field in order that the rising edges of each pulse are used as a clock signal for flip-flops (FF) 3, 4 and 9. A pair of D-FFs 3, 4 latch the input signal at the rising edge of the clock signal. An exclusive OR gate 5, a three-input NAND gate 6, an inverter 7, an OR gate 8, and a J-K FF 9 are also provided. The J-K FF 9 reads the input signals at the rising edge of the clock signal. 
     FIGS. 3(a)-3(j) are operation timing diagrams for the circuit in FIG. 2 and show the waveforms corresponding to the signals a through j, respectively. The frame discriminate code data a and the field discriminate code data b are latched by FFs 3 and 4, respectively, at the rising edge of the clock signal c for each field and converted into the signals d and e, respectively. The exclusive OR of the frame discriminate code data &#34;a&#34; and the latch output d of the field discriminate code data FF 3 is generated by the gate 5 to produce the signal f. That is, the signal f becomes a positive pulse at the start of each frame. 
     The signal g is obtained by entering the inverted signal b and the signals f and e into the NAND gate 6, and it becomes H (high level) only when the signal b is H, the signal f is L (low level) and the signal e is L. That is, the signal g becomes H within the duration of the second field only while the frame discriminate code data &#34;a&#34; remains unchanged with associated the field discriminate code data &#34;b&#34; being first L and then H. 
     The signal h is a logical sum of the inverted signal b and the signal g and it is H within the first field duration and when the signal g is H. The signal j, indicatingg the regenerative operation mode, is obtained by entering the signal g and the signal h into the J-K FF 9 and latching them with the clock signal i for each field. It should be assumed, however, that the rise of the clock signal i is between the change timing of the field discriminate code data and the rise of the clock signal c. In addition, it is assumed that the Q output signal of the J-K FF 9 becomes H when the J and K input signals to the J-K FF 9 are all H, it becomes L when the J and K input signals are all L, and it remains unchanged when the J input signal is L and the K input signal is H. 
     The condition under which the signal j is set to H occurs when the signals g and h are all H, that is, the signal j is set to H only when the signals f and e are all L and the signal b is H. In other words, the above condition occurs when there is no frame change at the time of the field shift from the first field to the second field. Under this condition, it is detected that the VDP is in the normal regeneration mode and not in the specific regeneration mode such as the reverse regeneration mode or the like. 
     The conditions under which the signal j is reset to L occurs when the signals g and h are all L, that is, the signal j is reset to L when a frame change occurs at the time of the field shift from the first field to the second field. In this case, it is detected that the VDP is in an operation mode such as the reverse regeneration mode, fast-forward mode, or the like. 
     It would be understood from the embodiment that the discrimination of the VDP operation is enabled automatically by monitoring the signal j. 
     As set forth hereinabove, since the discrimination of the VDP operation mode is enabled automatically by the regeneration signal from the VDP according to the present invention, the discrimination in the case of an SWS processor connected to the VDP is enabled automatically at the SWS processor side. In addition, in the SWS processor, although an SWS data-inserted part in the regenerated video format signal is mask-processed to the black level, for example, and then sent out to the monitor, this detected signal may also be used for the purpose of preventing erroneous mask-processing while the VDP is in the specific operation mode.