JPS6158080B2 - - Google Patents

Description

[Detailed description of the invention]

The present invention relates to an apparatus for converting a field sequential color television signal obtained from a field sequential color television imaging device into a simultaneous color television signal using a plurality of field memories. Field-sequential type color television imaging devices can be relatively simple and compact in construction compared to simultaneous type color television imaging devices; for example, devices incorporating solid-state image sensors are used in endoscope devices. There is. However, the field sequential method is
Because it is different from the NTSC system, images cannot be displayed on commonly used NTSC color television receivers without the use of some kind of scan conversion device. For example, Japanese Patent Laid-Open No. 53-90685 describes an example of such a field sequential-simultaneous color television signal conversion device. In this known device, for example, three
The signals for each field of each color obtained in chronological order are sequentially stored in the field memory assigned to each color signal, and each color signal of red, green, and blue is completely stored in each field memory. After the field memory is stored, all the field memories are read out simultaneously to take out each color signal at the same time, so that a color image can be displayed on a current television receiver. However, with such a conversion device, a simultaneous color television signal that can be displayed on a receiver cannot be obtained until the red, green, and blue color signals are completely stored in each field memory. During the reading period, that is, the period when the image is displayed on the receiver, the color television signal supplied from the imaging device is discarded, and at the same time, the signal supplied from the imaging device is stored in the field memory. teeth,
The disadvantage of the receiver is that it does not display images. This publication also states that one of the three primary color signals is not stored in the field memory, but is supplied to the receiver together with the other two color signals that are simultaneously read out from the two field memories. Although such a configuration eliminates the signal being discarded, it does not solve the problem that the television signal is not supplied to the receiver during the period of storage in the field memory. In order to eliminate this drawback, it is possible to provide two field memories for each color signal, so that when one is in the read state, the other is in the write state, and repeat writing and reading alternately. . In this way, the television receiver is always supplied with a color television signal, and the sequential color television signal is not discarded. However, such a conversion device requires twice as many field memories as the number of color signals. For example, when using the three primary color signals of red, green, and blue, six field memories are required. Therefore, the structure has the drawbacks of being complicated and expensive. Although field memory requires large capacity, such memory is currently still expensive. An object of the present invention is to eliminate the above-mentioned drawbacks of the conventional art, to make it possible to reduce the required number of memories to only one more than the number of color information, and thus to make the construction simple and inexpensive. Moreover, the field sequential system can effectively convert the color television signal supplied from the sequential imaging device into a simultaneous color television signal without discarding it, and can always output the simultaneous color television signal.
It is an object of the present invention to provide a simultaneous color television signal conversion device. The conversion device of the present invention includes a number of field or frame memories equal to the number of color information obtained from a field-sequential color television imaging device plus one, and a field or frame memory in which the field-sequential color television signal is sequentially stored for each successive field or frame. means for reading out all the memories other than one memory that is in a storage operation; and means connected between the memory and each color signal output terminal equal to the number of color information, and a means for reading out all the memories except one memory that is in a storage operation; The apparatus is characterized by comprising a switching means for supplying color television signals of each color from a memory located in the memory to a predetermined color signal output terminal. The present invention will be described in detail below with reference to the drawings. FIG. 1 shows the structure of an example of a conventional field sequential-simultaneous color television signal. A field sequential color television signal supplied from a field sequential color television camera 1 is converted into a digital signal by an A/D converter 2. This digitized color television signal is supplied to the input terminal of the distributor 3. This distributor 3 has three contacts 3R, 3G, and 3B that are switched for each field, and these contacts are connected to input terminals of field changeover switches 4R, 4G, and 4B, respectively. These switches 4R, 4G and 4B each have two contacts 4R ₁ , 4R ₂ ; 4G ₁ , 4G ₂ and 4B ₁ , 4B ₂ . These contacts are connected to a pair of red field memories 5R ₁ , 5R ₂ , a pair of green field memories 5G ₁ , 5G ₂ , and a pair of blue field memories 5
Connect to the input terminals of B ₁ and 5B ₂ respectively. The output terminals of these field memories are connected to contacts 6R ₁ , 6 of field changeover switches 6R, 6G, and 6B.
R ₂ , 6G ₁ , 6G ₂ and 6B ₁ , 6B ₂ , and the output terminals of these switches are connected to output terminals 8R, 8G and 8B of the entire conversion device through D/A converters 7R, 7G and 7B, respectively. Connecting.
Memory drive circuits 9R ₁ , 9R ₂ ; 9G ₁ ,
9G ₂ ; 9B ₁ and 9B ₂ are provided, and these are controlled by the control circuit 10.
Controlled by Moreover, this control circuit 10 allows
Distributor 3, switch 4R, 4G, 4B, 6R, 6
G and 6B are also synchronously controlled. The operation of the above-mentioned conventional conversion device is as shown in the table below, and it can convert the sequential color television signal supplied from the sequential television camera 1 into a simultaneous color television signal without discarding it. Signals are constantly supplied to 8R, 8G, and 8B.

【table】

[Table] However, in such a conventional conversion device, six field memories 5R ₁ , 5R ₂ , 5G ₁ , 5G ₂ , 5
B ₁ , 5B ₂ are required, thus making the construction complex and particularly expensive. At present, large-capacity memories such as field memories are expensive, and as many as six such expensive memories are required, making the entire conversion device extremely expensive. FIG. 2 is a block diagram showing the structure of an example of a field sequential-to-simultaneous color television signal conversion apparatus according to the present invention. In this example, as the imaging device 21
Using a self-scanning solid-state imaging device such as a CCD or BBD, an image of the subject is formed on an imaging device 21 via a rotating filter 22. The rotating filter 22 has a filter portion 2 that transmits red, green and blue light, respectively.
1R, 21G and 21B, motor 23
is rotated at a constant speed in the direction shown by the arrow.
Further, the motor 23 is driven and controlled by a motor drive circuit 24. Imaging device 21
The field-sequential color television signal obtained is first converted into a digital signal by an A/D converter 25, and then supplied to the input terminal of a distributor 26. This distributor has four switching contacts 26-1 to 26
-4, and these can be switched sequentially for each field. In the present invention, the number of field memories equal to the number of color signal types plus 1 is provided, so in this example, 4 field memories are provided.
Field memories 27-1 to 27-4 are provided, and contacts 26-1 to 26-4 of the distributor 26 are connected to respective input terminals of these field memories. Furthermore, these field memories 27-
The output terminals 1 to 27-4 are connected to the subsequent switch group. This switch group consists of three switches 28
R, 28G, 28B, and each switch has four contacts connected to four input terminals. The four contacts 28R ₁ to 28R ₄ of the switch 28R are connected to the output terminals of the memories 27-1 to 27-4, respectively, and the contacts 28G ₁ to 28G ₄ of the switch 28G and the contacts 28B ₁ to 28B ₄ of the switch 28B are connected in the same way. are connected to the respective output terminals of the memories 27-1 to 27-4. Switch 28R, 28G, 28
The output terminals of B are connected to D/A converters 29R and 2, respectively.
Output terminals 30R, 30G,
30B respectively. field memory 2
Drive circuits 31-1 to 31-4 are provided for controlling write and read operations of 7-1 to 27-4. These drive circuits 31-1 to 31-4, the motor drive circuit 24, the drive circuit 32 of the imaging device 21, and the switches 28R, 28G, and 28B are synchronously controlled by a control circuit 33. The operation of the conversion device of the present invention is shown in the following table.

[Table] The operation is clear from the table above. For example, in the state shown in FIG. 2, the green filter portion 22G is in the optical path, a green signal B ₄ is supplied from the imaging device 21, and this signal B ₄ is transmitted to the contact 26 of the switch 26.
-3 and is written to the field memory 27-3. During this time, other field memories 27-1, 27
-2 and 27-4 are in the read state. The memory 27-1 stores the blue signal B ₃ , and the 2
Red signal R ₄ is stored in 7-2, and 27
-4 stores the green signal G3. The blue signal _B3 of the memory 27-1 is supplied to the output terminal 30B via the switch 28B, and the red signal _R4 of the memory 27-2 is supplied to the output terminal 3 via the switch 28R.
0R, green signal G ₃ of memory 28-4
is supplied to output terminal 30G via switch 28G. In this way a simultaneous color television signal is obtained. In the present invention, as can be seen from the above table, the simultaneous color television signals obtained at these output terminals may sometimes slip in relation to the rotational phase of the rotary filter 22, but there is almost no change in image information between successive fields. Visually, there is no problem at all since there is no problem. In this way, the output terminals 30R, 30G, 30
After processing the simultaneous color television signal obtained in B as usual and adding necessary synchronization signals, etc.
It can be supplied to an NTSC color television receiver to display color images. The invention is not limited only to the examples described above, but can be modified in many ways. For example, in the example above, the three primary colors of red, green, and blue were used.
Color information for two or four or more colors can also be used if necessary. In either case, it is sufficient to provide the number of field memories equal to the number of color information plus one. Further, although the above-described example is shown as performing interlaced scanning, it is not necessarily necessary to perform interlaced scanning, and in such a case, the field memory becomes a frame memory. Furthermore, although the rotating filter 22 is provided in front of the imaging device 21 in the example shown in FIG. 2, this rotating filter may also be provided in front of the illumination light source. Alternatively, three color light sources can be provided separately and operated sequentially. In addition, in the above example, the switches 28R, 28G, 2
D/A converters 29R, 29G, 29 after 8B
B is provided, but field memories 27-1 to 27
A D/A converter may be provided on the output side of -4, but
In this case, four D/A converters are required.
Furthermore, an analog memory can be used as the memory, and in such a case, the A/D converter and the D/A converter are all unnecessary. According to the present invention described above, the number of field memories or frame memories can be reduced compared to the conventional one, making the configuration simple and inexpensive. Moreover, since all field sequential signals are converted without being discarded and simultaneous signals are always supplied to the output terminal, the conversion efficiency is significantly higher than that of the conventional method.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of an example of a conventional field sequential-simultaneous color television signal conversion device, and FIG. 2 is a block diagram showing the configuration of an example of the field sequential-simultaneous color television signal conversion device according to the present invention. It is. 21... Imaging device, 22... Rotating filter, 2
3...Motor, 24...Motor drive circuit, 2
5...A/D converter, 26...Distributor, 27-1
~27-4...Field memory, 28R, 28
G, 28B...Switch, 29R, 29G, 29
B...D/A converter, 30R, 30G, 30B...
...Output terminal, 33...Control circuit.

Claims (1)

[Claims] 1. In an apparatus for temporarily storing a field sequential color television signal obtained from a field sequential color television imaging device in a plurality of field or frame memories, and simultaneously reading out each color signal and converting it into a simultaneous color television signal, the field sequential color television signal is a field or frame memory whose number is equal to the number of color information obtained from the color television imaging device plus one; means for storing the field-sequential color television signal in the sequential memories for each successive field or frame; means for reading out and operating all the memories except for one memory that is in the read state; and a color television set connected between the memory and each color signal output terminal equal to the number of color information, each color from the memory being in the read state; and switching means for supplying a signal to a predetermined color signal output terminal.