JP3231133B2 - Digital video camera device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital video camera apparatus for performing signal processing digitally.

[0002]

2. Description of the Related Art FIG. 5 shows a conventional digital video camera apparatus which performs AD conversion of a signal from a solid-state image sensor and processes the signal in a digital domain. In FIG. 5, lens element 1, C
The video signal that has passed through the solid-state imaging device 2 such as a CD has a correlation 2
The signal is converted into a digital signal by the AD converter 5 through the double sampling circuit 3 and the gain adjusting circuit 4, and the digital signal processing circuit 6 generates the digital luminance signal Y and the digital chrominance signal C.

The digital luminance signal Y is supplied to a DA converter 7
Is returned to an analog signal, and is input to the selector 9 via the low-pass filter 8. The luminance signal Y from the external input terminal 10 is input to the selector 9 as an analog signal. The selector 9 selects either the camera input luminance signal Y or the external input luminance signal Y. The selected signal passes through a low-pass filter 11, becomes a digital signal in an AD converter 12, is input to a digital signal recording / reproducing device 13 such as a digital VTR, and is recorded on a tape 14.

On the other hand, the digital chrominance signal C generated by the digital signal processing circuit 6 is converted back to an analog signal by a DA converter 15 and input to a selector 17 via a low-pass filter 16. The color signal C from the external input terminal 18 is input to the selector 17 as an analog signal. The output signal of the selector 17 is output from the demodulator 19 to the color difference signal R.
-Y and BY are generated, and the AD converters 20 and 21 are respectively generated.
The digital signal is sent to the digital signal recording / reproducing device 13 and is recorded on the tape 14 together with the luminance signal Y.

At the time of reproduction, the digital video signal recorded on the tape 14 is reproduced by the digital signal recording / reproducing device 13, and the digital reproduced luminance signal Y is converted by the DA converter 2
The signal is returned to an analog signal at 2 and is input to a selector 24 via a low-pass filter 23, and is output as a luminance signal Y from an output terminal 25. At the time of recording, the output of the selector 9 is sent to the selector 24 as it is, and the output terminal 2
5 is monitored.

On the other hand, the digital reproduced color difference signals RY and BY reproduced by the digital signal recording / reproducing device 13 are:
It is returned to an analog signal in the DA converters 26 and 27,
The light passes through low-pass filters 28 and 29, is modulated by a modulator 30, and is output as a color signal C from an output terminal 32 via a selector 31. At the time of recording, the selector 17
Is sent to the selector 31 as it is, and is monitored by the output signal C.

FIG. 6 shows another example of a conventional digital video camera apparatus. The digital signal processing circuit 6 uses a digital luminance signal Y and digital color difference signals RY, B-.
Y, and the digital color difference signals RY, BY
Is modulated by a modulator 33 to generate a digital color signal C. The configuration and operation of the other parts are the same as in FIG.

[0008]

However, in the above-mentioned conventional example, since the digital signal of the camera section is returned to analog once, many components such as an AD converter and a DA converter are required, and the amount of hardware is enormous. Problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problem, and has as its object to provide a digital video camera device having a small number of components.

[0010]

According to a first aspect of the present invention, when a signal from a solid-state imaging device is A / D converted and processed in a digital domain, and connected to an existing digital signal recording / reproducing apparatus,
The digital chrominance signal of the camera section is sent to a modulation circuit at a sampling frequency of, for example, four times the subcarrier frequency, and the chrominance output signal of the digital recording / reproducing apparatus is frequency-converted and then modulated in the digital domain. And

According to a second aspect of the present invention, when a signal from a solid-state imaging device is A / D converted and processed in a digital domain, and when connected to an existing digital signal recording / reproducing apparatus, the sampling frequency of a digital color difference signal of a camera unit is converted. Further, the color difference signal to be output is modulated in an analog domain.

According to a third aspect of the present invention, in the first or second aspect, a signal from the solid-state imaging device is A / D converted and processed in the digital domain, and when connected to an existing digital signal recording device, the digital signal recording is performed. It is characterized in that the external input luminance signal sent to the device is AD-converted at the sampling frequency of the digital signal recording device, and the external input chrominance signal sent to the digital signal recording device is AD-converted at, for example, four times the subcarrier frequency.

[0013]

According to the first to third aspects of the invention, the number of parts is reduced, and connection between the existing digital signal processing camera and the existing digital VTR becomes easy.

[0014]

FIG. 1 shows a first embodiment of the present invention, and portions corresponding to those in FIG. 5 are denoted by the same reference numerals. In FIG. 1, the video signal that has passed through the lens element 1 and the solid-state image sensor 2 is
A via the correlated double sampling circuit 3 and the gain adjustment circuit 4
The signal is converted into a digital signal by the D converter 5. This AD converter 5
Is sampled at the clock frequency (MCLK) of the solid-state imaging device 2. The digital signal processing circuit 6 generates a digital luminance signal Y and a digital chrominance signal C from the camera input signal.

After the sampling frequency of the digital luminance signal Y is converted by the frequency converter 34 from the clock frequency (MCLK) of the solid-state imaging device 2 to the sampling frequency (about 13.5 MHz) of the digital signal recording / reproducing device 13, the selector 35 Sent to

The luminance signal Y from the external input terminal 10
Is sampled by an AD converter 36 at the sampling frequency (about 13.5 MHz) of the digital signal recording / reproducing device 13 and AD-converted, and then sent to the selector 35.
The selector 35 selects either the camera input luminance signal Y or the external input luminance signal Y and inputs it to the digital signal recording / reproducing device 13.

On the other hand, the digital color signal C generated by the digital signal processing circuit 6 is sent to the selector 37. The color signal C from the external input terminal 18 is
In four times the sampling frequency 4f _sc subcarrier frequency f _sc
And is converted into a digital signal. Selector 3
In step 7, either the camera input color signal C or the external input color signal C is selected. The output of the selector 37 is demodulated by the demodulator 19 and becomes digital color difference signals RY and BY. The sampling frequency of the color difference signal at this time is 4 _fsc , but the sampling frequency of the digital signal recording / reproducing device 13 is about 13.5 MHz, so that the frequency converters 39a and 39b are used for RY and BY respectively. Performs frequency conversion. Thus, the digital chrominance signal having the sampling frequency of 13.5 MHz is supplied to the digital signal recording / reproducing apparatus 1.
3 and is recorded on the tape 14 together with the digital luminance signal Y.

At the time of reproduction, the digital video signal recorded on the tape 14 is reproduced by the digital signal recording / reproducing device 13. The digital reproduction luminance signal is supplied to the selector 40.
The signal is converted back to an analog signal at the sampling frequency of the digital signal recording / reproducing device 13 in the DA converter 41 via the low-pass filter 42 and output from the output terminal 25 as the luminance signal Y. At the time of recording, the output of the selector 35 is sent to the selector 40 as it is, and the luminance signal Y of the output terminal 25 is monitored.

On the other hand, the reproduced digital reproduced color difference signals RY and BY are subjected to frequency conversion by frequency converters 43 and 44, respectively. The sampling frequency at this time is the sampling frequency in the digital signal recording / reproducing device 13.
It is converted into 4f _sc from 13.5 MHz. The frequency-converted color difference signals are sent to selectors 45 and 46, respectively. These are modulated by the digital modulator 47 to become digital color signals. After being converted back to an analog signal by the DA converter 48 at a sampling frequency of 4 _fsc , the signal passes through the low-pass filter 49 and is output from the output terminal 32 as a color signal C. Incidentally, at the time of recording, the output of the demodulator 19 is sent to the left selector 45 of the sampling frequency 4f _sc, monitoring the chrominance signal C at the output terminal 32.

FIG. 2 shows a second embodiment of the present invention.
The parts corresponding to are denoted by the same reference numerals.

In this embodiment, the configuration and operation during recording and the configuration and operation during reproduction with respect to the luminance signal Y are the same as those in FIG. Therefore, the configuration and operation at the time of reproduction for color signals will be described.

The digital reproduced color difference signals RY and BY reproduced by the digital signal recording / reproducing device 13 are sent to selectors 45 and 46, respectively. These are converted back into analog signals in the DA converters 50 and 51 at the sampling frequency of the digital signal recording / reproducing device 13, respectively.
The signal passes through the low-pass filters 52 and 53, is analog-modulated by the modulator 30, and is output to the output terminal 32 as a color signal C. At the time of recording, the outputs of the frequency converters 39a and 39b are sent to the selectors 45 and 46, and after performing DA conversion and modulation, the color signal C at the output terminal 32 is monitored.

FIG. 3 shows a third embodiment, and FIGS.
Parts corresponding to those in FIG. 6 are denoted by the same reference numerals. In FIG. 3, the digital signal converted by the AD converter 5 at the clock frequency (MCLK) of the solid-state imaging device 2 is applied to a digital signal processing circuit 6, where the digital luminance signal Y and the digital color difference signals RY, B- Y is generated.

The digital luminance signal Y is converted back to an analog signal at a sampling frequency MCLK by a DA converter 54 and is input to a selector 56 via a low-pass filter 55. The luminance signal Y from the external input terminal 10 is input to the selector 56 as an analog signal. Selector 5
In step 6, either the camera input luminance signal Y or the external input luminance signal Y is selected. The selected signal passes through a low-pass filter 57, and is subjected to an AD converter 58 at a sampling frequency (about 13.5 MHz) in the digital signal recording / reproducing device 13.
The signal becomes a digital signal in z), and is input to the digital signal recording / reproducing device 13.

On the other hand, the digital color difference signals RY and BY generated by the digital signal processing circuit 6 are sent as digital signals to the selectors 59 and 60, respectively. The color signal C of the external input terminal 18 is converted into a digital signal by the AD converter 61, and the external input color difference signal R is output by the demodulator 62.
-Y and BY are generated. The selectors 59 and 60 select either the camera input color difference signal or the external input color difference signal. At this time, the sampling frequency of the output color difference signals of the selectors 59 and 60 is 4 _fsc , while the sampling frequency of the digital signal recording / reproducing device 13 is 13.5 MHz. The frequency conversion is performed by the frequency converters 39a and 39b, respectively. Thus, the digital chrominance signal having the sampling frequency of 13.5 MHz is input to the digital signal recording / reproducing device 13 and recorded on the tape 14 together with the luminance signal Y.

At the time of reproduction, the digital reproduction luminance signal reproduced from the tape 14 by the digital signal recording / reproducing device 13 is sampled by the DA converter 22 at the sampling frequency (about 1).
3.5MHz) and converted back to an analog signal.
3 and is input to the selector 40 and output from the output terminal 25 as a luminance signal Y. At the time of recording, the output of the selector 56 is sent to the selector 40 as it is, and the luminance signal Y of the output terminal 25 is monitored.

On the other hand, it is converts reproduced digital reproduced color-difference signals R-Y, B-Y from the sampling frequency 13.5MHz to 4f _sc by the frequency converter 43, 44. The color difference signals subjected to the frequency conversion are sent to selectors 45 and 46, respectively, and further modulated by a digital modulator 47 to become color signals. Then it passes through the back into an analog signal a low-pass filter 49 in the DA converter 48 at a sampling frequency 4f _sc, the chrominance signal C at the output terminal 32. At the time of recording, the outputs of the selectors 59 and 60 are set to the sampling frequency 4f.
_{The signal sc} is sent to the selectors 45 and 46 and output terminal 32
Is monitored by the color signal C.

FIG. 4 shows a fourth embodiment, and FIGS.
Parts corresponding to those in FIG. 3 are denoted by the same reference numerals.

In this embodiment, the configuration and operation at the time of recording and the configuration and operation at the time of reproduction relating to the luminance signal Y are the same as those of the third embodiment. Therefore, the configuration and operation at the time of reproduction for color signals will be described.

In FIG. 4, digitally reproduced color difference signals RY, B reproduced by the digital signal recording / reproducing device 13 are shown.
−Y is input to the selectors 45 and 46. These are converted into analog signals in the D / A converters 50 and 51 at a sampling frequency of 13.5 MHz, and the low-pass filters 52 and 53
, And is modulated by the modulator 30 and output to the output terminal 32. At the time of recording, the outputs of the frequency converters 39a and 39b are sent to the selectors 45 and 46 as they are, and the color signal C of the output terminal 32 is monitored.

[0031]

As described above, according to the first invention, the color difference signal of the camera section is sent to the modulator at the sampling frequency of 4 _fsc , and the color difference output signal of the digital recording / reproducing apparatus is output when the image is output. Convert the sampling frequency to 4f _sc ,
The color signal is generated by modulation in the digital domain. In the second invention, the input color difference signals RY, B-
Converting the sampling frequency of Y from 4f _sc to the sampling frequency of the digital signal recording / reproducing device, and, when outputting a video, DA converting the digital color difference signal at the above sampling frequency and modulating in the analog domain to convert the color signal. It is generated. In a third aspect based on the first or second aspect, the external input luminance signal sent to the digital signal recording / reproducing device is AD-converted at the sampling frequency of the digital signal recording / reproducing device, and the external input color signal sent to the digital signal recording / reproducing device is converted. The signal is AD-converted at a frequency four times the sub-carrier frequency.
Therefore, according to the first to third aspects, the number of parts is reduced,
There is an effect that an existing digital camera can easily be connected to an existing digital signal recording / reproducing device such as a digital VTR.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a first embodiment of the present invention.

FIG. 2 is a block diagram showing a second embodiment of the present invention.

FIG. 3 is a block diagram showing a third embodiment of the present invention.

FIG. 4 is a block diagram showing a fourth embodiment of the present invention.

FIG. 5 is a block diagram showing a conventional digital video camera device.

FIG. 6 is a block diagram showing another example of a conventional digital video camera device.

[Explanation of symbols]

 2 solid-state imaging device 6 digital signal processing circuit 13 digital signal recording / reproducing device 36,38 AD converter 39a, 39b frequency converter 43,44 frequency converter 47 digital modulator 50,51 DA converter

Claims (3)

(57) [Claims] A digital video camera device configured to transmit a digital luminance signal and a digital color difference signal obtained by processing an image signal of an image sensor by digital signal processing means to a digital signal recording / reproducing device; A frequency converter for converting the sampling frequency of the reproduced chrominance signal of the signal recording / reproducing apparatus from the sampling frequency of the digital signal recording / reproducing apparatus to a predetermined multiple of the subcarrier frequency; and, during recording, the output digital chrominance signal of the digital signal processing means. And a digital modulator for modulating an output signal of the frequency converter during reproduction. 2. A digital signal recording / reproducing apparatus which sends a digital luminance signal obtained by processing an image pickup signal of an image pickup device by digital signal processing means and a digital color difference signal having a sampling frequency several times the subcarrier frequency to a digital signal recording / reproducing apparatus. In the digital video camera device thus formed, a frequency converter for converting a sampling frequency of the digital chrominance signal into a sampling frequency of the digital signal recording / reproducing device at the time of recording; and a reproducing chrominance of the frequency converter or the digital signal recording / reproducing device. A digital video camera device, further comprising a DA converter for DA-converting a signal at a sampling frequency of the digital signal recording / reproducing apparatus. 3. The digital video camera device is configured to receive an analog luminance signal and an analog chrominance signal from the outside and send them to the digital signal recording device, and the external input analog luminance to be sent to the digital signal recording device. An AD converter for AD converting a signal at the sampling frequency of the digital signal recording device, and an AD converter for AD converting the external input analog color signal to be sent to the digital signal recording device at a frequency that is a predetermined multiple of a subcarrier frequency. 2. The device according to claim 1, wherein
Or the digital video camera device according to 2.