JP3878233B2 - Video signal conversion apparatus and facsimile apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a video signal conversion apparatus that converts a video signal into predetermined image data, and a facsimile apparatus that performs facsimile transmission and copying based on the image data converted by the video signal conversion apparatus.
[0002]
[Prior art]
Conventionally, as a facsimile apparatus for converting a video signal obtained from a television or a video into image data and performing facsimile transmission and copying, the one shown in Japanese Patent Laid-Open No. 5-336297 has been proposed. Such a facsimile apparatus captures a luminance signal from an input video signal, and A / D converts the captured luminance signal by a conversion clock four times (14.32 MHz) of the color subcarrier fsc (3.58 MHz). In addition, the digital signal is binarized and stored in the memory. After the storage of one field image in the memory is completed, the field image stored in the memory is subjected to MH encoding, MR encoding, By performing redundancy suppression coding such as MRR coding and performing modulation processing by a modem, a television or video Sending it was configured to allow for the other party facsimile apparatus connected via a telephone line video signal as a facsimile image data obtained from such.
[0003]
[Problems to be solved by the invention]
  By the way, in recent years, the contents of image processing have been advanced, and pseudo gradation image processing by an error diffusion method has been adopted in a facsimile apparatus. However, in the conventional apparatus, as shown in FIG. 14, a document reading unit (21, 24) for reading a document and converting it into a facsimile signal and an image processing unit (41, 42) for converting a video signal into a facsimile signal are provided. Because it is independent, if pseudo-tone image processing by error diffusion method is adopted for each processing unit, the circuit scale increases, the processing circuit becomes complicated, and the cost greatly increases. was there.
[0004]
The present invention relates to a video signal conversion apparatus capable of performing binarization processing on image data and an input video signal read by an original reading unit without increasing the circuit scale and complication of a processing circuit, and The object is to provide a facsimile machine.
[0005]
[Means for Solving the Problems]
  In order to achieve the above object, the present invention provides:From the video signal input externally by the first deviceVideo signal processing means for separating the synchronization signal and the luminance signal;
  A / D conversion means for converting the luminance signal separated by the video signal processing means into a digital signal;
  Storage means for storing the digital signal converted by the A / D conversion means;
  D / A conversion means for converting a digital signal read from the storage means into an analog signal;
  By the D / A conversion meansFor analog signalConvertedLuminanceAn external output means for outputting a signal to the outside;
  By the A / D conversion means in the storage meansDigital signalConvertedThe luminance signal from the first device is stored in synchronization with the synchronization signal separated by the video signal processing means,When the number of screens of data stored in the storage means exceeds a predetermined number, it returns to the standby stateAt the same time, the luminance signal stored in the storage means is read in synchronization with the transfer clock input from the second device to the outsideAnd a control means.
[0006]
  In the present invention, the external input transfer clock is a drive clock for driving an image sensor that reads image data from a document,
  The external output means externally outputs the analog signal converted by the D / A conversion means as an output signal of the image sensor.
[0007]
  Furthermore, the present invention is characterized in that the control means temporarily pauses the data reading by the storage means when the external input transfer clock pauses before the data reading of the storage means is completed.
[0008]
  Furthermore, the present invention provides an operation input means for instructing to take in an external input video signal,
  The control means is characterized in that when the capture instruction is made by the operation input means, the data storage by the storage means is performed in synchronization with the synchronization signal separated by the video signal processing means.
[0009]
  5. The video signal conversion apparatus according to claim 1, further comprising an enlargement processing unit that performs an enlargement process on the digital signal read from the storage unit. .
[0010]
  Furthermore, the present invention provides data compression means for compressing the digital signal converted by the A / D conversion means,
  Data decompression means for decompressing the digital signal compressed by the data compression means into a base signal;
  The storage means stores the digital signal compressed by the data compression means and decompresses the read digital signal by the data decompression means.
[0011]
  Furthermore, the present invention provides the video signal converter,
  Drive clock generating means for generating a drive clock for driving the image sensor;
  And binarization processing means for binarizing the image data read by the image sensor,
  The drive clock generation means outputs the generated drive clock as a transfer clock to the video signal converter,
  The binarization processing means is a facsimile apparatus characterized by binarizing the output signal output from the video signal converter.
[0012]
  Further, the present invention is characterized in that the facsimile main body is provided with a connection portion that enables the image sensor and the video signal converter to be selectively connected.
[0013]
  According to the present invention,From the first deviceWhen the video signal is externally input, the video signal processing means divides the synchronization signal and the luminance signal from the external input video signal, and the divided luminance signal is converted into a digital signal by the A / D conversion means. The control means stores the digital signal in the storage location of the memory address instructed in synchronization with the synchronization signal of the storage means in synchronization with the synchronization signal divided by the video signal processing means. AndFrom the second deviceWhen the transfer clock is externally input, the control means reads a digital signal from the storage means in synchronization with the external input transfer clock, for example, in accordance with a preset memory read start address, and D / A converts the read digital signal. After converting to an analog signal by means, and outputting to the outside by external output means,For example, the first deviceVideo signals obtained from TV and video can be converted into arbitrary image data, and the converted image data, Second equipmentCan be output in synchronization with the transfer clock.Further, since the control means returns to a standby state when the number of screens of data stored in the storage means exceeds a predetermined number, the data is prevented from being interrupted in the middle of one screen when data is output.
[0014]
  Also according to the present invention,From the first deviceWhen the video signal is externally input, the video signal processing means divides the synchronization signal and the luminance signal from the external input video signal, and the divided luminance signal is converted into a digital signal by the A / D conversion means. The control means stores the digital signal in the storage means in synchronization with the synchronization signal divided by the video signal processing means. AndSecond deviceWhen the drive clock for driving the image sensor is externally input, the control means reads the digital signal from the storage means in synchronization with the externally input drive clock, and the read digital signal is analogized by the D / A conversion means. After converting to a signal, by outputting to the outside by an external output means,For example, the first deviceVideo signals obtained from televisions and videos can be converted into arbitrary image data, and the readout of the converted image data is synchronized with the drive clock of the image sensor, so that the image data is output as the output signal of the image sensor. Can be output.
[0015]
  Further according to the present invention,From the first deviceWhen the video signal is externally input, the video signal processing means divides the synchronization signal and the luminance signal from the external input video signal, and the divided luminance signal is converted into a digital signal by the A / D conversion means. The control means stores the digital signal in the storage means in synchronization with the synchronization signal divided by the video signal processing means. AndFrom the second deviceWhen the transfer clock is externally input, the control means reads the digital signal from the storage means in synchronization with the external input transfer clock, and converts the read digital signal into an analog signal by the D / A conversion means. When the image data is output to the outside by the output means, and the transfer clock input is paused in the external output state of the image data, the control means pauses the reading of the digital signal from the storage means, and the external input of the transfer clock is resumed. Then, the digital signal is read out from the storage means again in synchronization with the external input transfer clock, and the image data obtained from the TV, video, etc. is converted into arbitrary image data by externally outputting the image data by the external output means. Can be converted, and reading the converted image dataSecond deviceThe image data can be externally output in complete synchronization with the transfer clock by performing the synchronization in synchronization with the transfer clock and temporarily stopping the reading of the image data in response to the temporary suspension of the transfer clock.
[0016]
  Further according to the present invention,From the first deviceWhen an input instruction is made by the operation input means in a state where the video signal is externally input, the video signal processing means divides the synchronization signal and the luminance signal from the external input video signal, and the divided luminance The signal is converted into a digital signal by the A / D conversion means, and the control means stores the digital signal in the storage means in synchronization with the synchronization signal divided by the video signal processing means. AndFrom the second deviceWhen the transfer clock is externally input, the control means reads the digital signal from the storage means in synchronization with the external input transfer clock, and converts the read digital signal into an analog signal by the D / A conversion means. By outputting to the outside by output means,For example, the first deviceA video signal of an arbitrarily set video obtained from a TV or a video can be converted into arbitrary image data, and the converted image dataSecond deviceCan be output in synchronization with the transfer clock.
[0017]
  Further according to the present invention,From the first deviceWhen the video signal is externally input, the video signal processing means divides the synchronization signal and the luminance signal from the external input video signal, and the divided luminance signal is converted into a digital signal by the A / D conversion means. The control means stores the digital signal in the storage means in synchronization with the synchronization signal divided by the video signal processing means. AndFrom the second deviceWhen the transfer clock is externally input, the control means reads the digital signal from the storage means in synchronization with the external input transfer clock, and after the read digital signal is enlarged by the enlargement processing means, the D / A conversion means By converting to an analog signal by, and outputting the analog signal to the outside by an external output means,For example, the first deviceVideo signals obtained from TV and video can be converted into arbitrary image data, and the converted image dataSecond deviceCan be output in synchronization with the transfer clock.
[0018]
  Further according to the present invention,From the first deviceWhen the video signal is externally input, the video signal processing means divides the synchronization signal and the luminance signal from the external input video signal, and the divided luminance signal is converted into a digital signal by the A / D conversion means. Thereafter, a digital signal compressed by the data compression means and compressed by the control means in synchronization with the synchronization signal divided by the video signal processing means is designated in synchronization with the synchronization signal of the storage means. Store in the address storage location. AndFrom the second deviceWhen the transfer clock is externally input, the control means reads out a digital signal compressed in accordance with, for example, a preset memory read start address from the storage means in synchronization with the external input transfer clock and outputs the read digital signal. After data expansion by the data expansion means, the analog signal is converted by the D / A conversion means, and the analog signal is output to the outside by the external output means.For example, the first deviceVideo signals obtained from TV and video can be converted into arbitrary image data, and the converted image dataSecond deviceCan be output in synchronization with the transfer clock. Further, since the control means returns to a standby state when the number of screens of data stored in the storage means exceeds a predetermined number, the data is prevented from being interrupted in the middle of one screen when data is output.
[0019]
  Further, according to the present invention, when a video signal is externally input to the video signal converter, the synchronization signal and the luminance signal are divided from the external input video signal by the video signal processing means, and the divided luminance signal is divided. Is converted into a digital signal by the A / D conversion means, and the control means stores the digital signal in the storage means in synchronization with the synchronizing signal divided by the video signal processing means. Then, when a driving clock for driving the image sensor is output from the facsimile main body and externally input to the video signal converter, the control means reads out the digital signal from the storage means in synchronization with the externally input driving clock, The read digital signal is converted into an analog signal by the D / A conversion means, and then externally output to the facsimile main body by the external output means. On the other hand, the analog signal externally output from the video signal conversion device in the facsimile main body is binarized. By performing binarization processing by the processing means, it is possible to perform facsimile transmission, copying, and the like using image data obtained by converting a video signal obtained from a television or video as a facsimile signal.
[0020]
  Further, according to the present invention, when a video signal is externally input to the video signal converter, the synchronization signal and the luminance signal are divided from the external input video signal by the video signal processing means, and the divided luminance signal is divided. Is converted into a digital signal by the A / D conversion means, and the control means stores the digital signal in the storage means in synchronization with the synchronizing signal divided by the video signal processing means. Then, by connecting the video signal converter to the connection part to which the image sensor is connected, the drive clock of the image sensor output from the facsimile body is externally input to the video signal converter, and the control means is externally input. The digital signal is read from the storage means in synchronization with the drive clock, and the read digital signal is converted into an analog signal by the D / A conversion means, and then externally output to the facsimile main body by the external output means. The analog signal externally output from the video signal converter is binarized by the binarization processing means, and the image data obtained by converting the video signal obtained from the television or video is transmitted as a facsimile signal as a facsimile signal. And copying.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0022]
  FIG. 1 is a schematic functional block diagram showing the electrical configuration of a video signal converter according to an embodiment of the present invention, FIG. 2 is an explanatory diagram showing the configuration of the video signal converter, and FIG. (B) shows a plane of the apparatus main body, and (c) shows a side surface of the apparatus main body. FIG. 3 is a schematic functional block diagram showing an electrical configuration of a facsimile apparatus to which the video signal conversion apparatus can be connected, where (a) is a state where an image sensor is mounted, and (b) is a video signal conversion instead of the image sensor. The state where the device is connected is shown. 4 is an external perspective view showing a state where the image sensor is mounted in the facsimile apparatus, and FIG. 5 is an external perspective view showing a state where the image sensor is removed from the facsimile apparatus. FIG. 6 is an external perspective view showing a state in which a video signal converter is connected in the facsimile apparatus.
[0023]
FIG. 7 is an explanatory diagram showing an example of connection between the video signal conversion device and another device. (A) shows a case where a television is connected as the video signal output device, and (b) shows a video and monitor as the video signal output device. When a television is connected as a device, (c) is a video camera as a video signal output device, and a television is connected as a monitor device. (D) is a facsimile device connected as an image data processing device, and the facsimile device and the other party. This shows a case where the side facsimile apparatus is connected via a public telephone line network. FIG. 8 is an explanatory diagram showing an example of connection between the video signal conversion apparatus and another apparatus. FIG. 8A shows a case where a television is connected as a video signal output apparatus and a facsimile apparatus is connected as an image data processing apparatus. When a video signal output device is connected to a video, a monitor device is connected to a television, and an image data processing device is connected to a facsimile device, (c) is a video signal output device connected to a video camera, a monitor device is connected to a television, and an image data processing device is connected to a facsimile device. Shows the case. FIG. 9 is an explanatory diagram showing a list of signal lines connecting the video signal conversion apparatus and the facsimile apparatus.
[0024]
FIG. 10 is a flowchart showing the video signal capturing operation in the video signal converter, FIG. 11 is a flowchart showing the image data transfer operation in the video signal converter, and FIG. 12 is a facsimile machine to which the video signal converter is connected. It is a flowchart which shows the facsimile transmission operation | movement in an apparatus.
[0025]
FIG. 13 is a schematic functional block diagram showing the electrical configuration of a video signal converter according to another embodiment of the present invention.
[0026]
Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS.
[0027]
1 to 6, reference numeral 1 denotes a video signal input unit to which a video signal as a video signal from a television or video is input, and 2 denotes a monitor signal for outputting the video signal input to the video signal input unit 1 to the outside. An output unit 3 is a video signal processing unit that separates a vertical synchronization signal, a horizontal synchronization signal, and a luminance signal from the video signal input to the video signal input unit 1, and 4 is a luminance signal that is separated by the video signal processing unit 3. An A / D conversion unit 5 for converting a digital signal of 8 bits per pixel is a memory unit for storing data digitally converted by the A / D conversion unit 4, and is configured by a DRAM or the like having a 1 Mbit capacity. Yes.
[0028]
  6 is a density adjusting unit that adjusts the density of the captured image, 7 is a capturing instruction unit that instructs to capture a video signal, and 8 is a transfer clock that receives a drive clock of an image sensor output from a facsimile apparatus or the like as a transfer clock. The input unit 9 controls the reference voltage of the A / D conversion unit 4 based on the density adjustment by the density adjustment unit 6 and is digitally transmitted by the A / D conversion unit 4 in response to the capture instruction from the capture instruction unit 7. The converted data is stored in the memory unit 5 in synchronism with the vertical synchronizing signal and horizontal synchronizing signal divided by the video signal processing unit 3, and in synchronism with the transfer clock input to the transfer clock input unit 8. 5 is a control unit that reads data stored in 5.
[0029]
10 is a D / A converter that converts the data read from the memory unit 5 by the controller 9 into an analog signal, 11 is a signal output unit that outputs the data analog-converted by the D / A converter 9 to the outside, 12 is a display unit for displaying the power supply state of the device and the data storage state of the memory unit 5, 13 is a battery for backup of the device body, and 14 is a power supply circuit unit for performing data backup of the memory unit 5 using the battery 13 as a power source. Yes, video signal input unit 1, monitor signal output unit 2, video signal processing unit 3, A / D conversion unit 4, memory unit 5, density adjustment unit 6, capture instruction unit 7, transfer clock input unit 8, control The video signal conversion apparatus is configured by the unit 9, the D / A conversion unit 10, the signal output unit 11, the display unit 12, the battery 13, and the power supply circuit unit 14.
[0030]
  As shown in FIG. 2, the video signal converter has a density adjustment knob (density adjustment unit 6) for adjusting the density level of the captured image and a capture button (capture instruction) for instructing the capture of the image. Section 7), a power supply LED 12a for displaying the on / off state of the power supply, and a memory LED 12b for displaying the number of images captured in the memory section 5, and a video input terminal (video signal input) on the plane. Section 1), a monitor output terminal (monitor signal output section 2), and a facsimile connection terminal (transfer clock input section 8 and signal output section 11) for connection with the facsimile apparatus, and further on the side face of the apparatus main body There is provided a power switch 19 for turning on / off the power supply. The display unit 12 includes the power LED 12a and the memory LED 12b.
[0031]
  In FIG. 3, reference numeral 21 denotes an image sensor for reading image data from a document (not shown), which is connected to the facsimile main body by a predetermined wired cord and is detachable from the facsimile main body. Reference numeral 22 denotes a document conveyance control unit that controls conveyance of a document read by the image sensor 21, 23 denotes a drive clock generation unit that generates a drive clock for driving the image sensor 21, and 24 denotes binary image data read by the image sensor 21. This is a read signal binarization processing unit for performing the conversion processing.
[0032]
Reference numeral 25 denotes a telephone line connected to the other party telephone or the other party facsimile machine via an unillustrated exchange, and 26 denotes the other party telephone connected via the acquired telephone line 25 while performing capture / release control of the telephone line 25. This is a communication unit that forms a call path with the counterpart facsimile machine, and includes a modem that performs modulation / demodulation necessary for data transmission / reception.
[0033]
  27 is a compression / decompression processing unit that compresses the data binarized by the read signal binarization processing unit 24, while decompressing the image data from the counterpart facsimile machine received by the communication unit 26, and 28 is a compression / decompression unit. A recording unit that prints an image based on the image data expanded by the processing unit 27 on a predetermined sheet, 29 is a numeric key for inputting the other party's telephone number and selected image number, and the like, a facsimile transmission instruction, a facsimile reception instruction, and a copy instruction An operation unit 30 including function keys for performing operations and the like, and 30 is a main control unit that controls each unit based on an instruction from the operation unit 29. The image sensor 21, the document conveyance control unit 22, the drive clock generation unit 23, the reading The signal binarization processing unit 24, the communication unit 26, the compression / decompression processing unit 27, the recording unit 28, the operation unit 29, and the main control unit 30 are used for facsimile. Location is configured.
[0034]
  As shown in FIG. 4, the facsimile apparatus configured as described above sets the document at a predetermined position when the image sensor 21 is mounted, so that the set document is the document conveyance control unit 22. The image sensor 21 reads the image data from the conveyed document, and the read signal binarization processing unit 24 reads the image data read by the image sensor 21. By performing the binarization process, the image data read from the document can be converted into facsimile data. As shown in FIG. 5, the image sensor 21 is removed when the image sensor 21 is removed from the facsimile main body. By scanning the top of the document with Take seen, the read signal binarizing section 24 the read image data may be facsimile data by binarization processing.
[0035]
  Further, as shown in FIG. 6, when a video signal converter is connected to the facsimile main body by a predetermined wired code instead of the image sensor 21 constituting the facsimile apparatus, the drive generated by the drive clock generator 23 constituting the facsimile apparatus is generated. The clock is input as a transfer clock to the transfer clock input unit 8 constituting the video signal conversion device, while the data output from the signal output unit 11 constituting the video signal conversion device is an image read by the image sensor 21. The data is input to the read signal binarization processing unit 24 as data. The image data transfer operation at this time will be described later.
[0036]
  In the video signal converter configured as described above, the video signal capturing operation will be described with reference to FIGS.
  In this embodiment, the video signal input to the video signal converter is an NTSC video signal having a vertical synchronizing signal period of 1/60 second and a horizontal synchronizing signal period of about 63.5 seconds. However, the present invention is not limited to this, and for example, a PAL system SECAM system or the like may be used.
[0037]
  First, in order to input a video signal to the video signal conversion apparatus, as shown in FIG. 7A, a video output terminal provided in the television and a video signal input unit 1 constituting the video signal conversion apparatus are predetermined. Or a video output terminal provided in the video and a video signal input unit 1 constituting the video signal converter as shown in FIG. 7B by a predetermined wired cord. At the same time, the monitor signal output unit 2 constituting the video signal conversion device and the video input terminal provided in the television are connected by a predetermined wired cord, or as shown in FIG. The video output terminal provided in the camera and the video signal input unit 1 constituting the video signal converter are connected by a predetermined wired cord, and the video signal converter is configured. When the Nita signal output unit 2 and a video input terminal provided in the television are connected by a predetermined wired cord and the video signal conversion device is turned on in such a connection state, the control unit 9 The display unit 12 is controlled to light the power LED 12a in green.
[0038]
  The power LED 12a is configured to be capable of switching light emission of two colors, green and red. When it is detected that the built-in battery 13 in the apparatus body is exhausted and becomes a predetermined voltage value or less, the detection is performed. Based on the result, the power LED 12a emits red light to alert the user, and when the video signal converter and the facsimile main body are connected by a predetermined wire, the battery 13 incorporated in the main body is consumed. In order to prevent this, power is supplied from the facsimile main body. At this time, the power LED 12a always emits green light without emitting red light.
[0039]
Then, in a standby state in which the video signal output device that constantly outputs the video signal and the video signal conversion device are connected by a predetermined wired cord and the video signal conversion device is turned on, the user can monitor When a desired image is displayed while confirming, when the user operates a take-in button provided on the upper surface of the apparatus main body (step F1), a take-in instruction unit in response to the operation of the take-in button 7, an image capture signal is output, and the control unit 9 responds to the image capture instruction signal with a predetermined number of screens of image data stored in the memory unit 5 (four screens in this embodiment). It is judged whether it is above (step F2).
[0040]
  At this time, when the control unit 9 determines that the number of screens of the image data stored in the memory unit 5 is less than the predetermined number (step F2), the control unit 9 is separated by the video signal processing unit 3. The vertical synchronization signal is detected (step F3), and when the control unit 9 detects the vertical synchronization signal, the number of lines of the image data is set to “0” (step F4) and the video signal processing unit The horizontal sync signal separated by 3 is detected (step F5).
[0041]
When the control unit 9 detects the horizontal synchronization signal (step F5), “1” is added to the number of lines of image data (step F6), and the number of lines plus “1” is predetermined. It is determined whether the number is 11 or more (11 lines in this embodiment) (step F7). If it is determined that the number of lines is greater than or equal to a predetermined number at this time, the control unit 9 again sets the number of lines of image data to “0”. (Step F8) and the horizontal synchronizing signal separated by the video signal processing unit 3 is detected (step F9).
[0042]
The reason for providing a delay of a predetermined number of lines from the end of the vertical synchronization signal interval to the actual start of image data acquisition is that the image at the center of the screen is acquired and noise is generated before and after the vertical synchronization interval. This is to prevent the occurrence.
[0043]
Then, each time the horizontal synchronizing signal is detected in the control unit 9 (step F9), one line of image data is captured (step F10), and a total of 220 lines of image data are captured.
[0044]
  The image data for one line is captured by the A / D conversion unit 4 converting the luminance signal, which is an analog signal, into 8-bit digital data per pixel based on the reference voltage, and the control unit 9 using the vertical synchronization signal. The memory address of the storage destination is sequentially generated on the basis of the horizontal synchronization signal and the digital data converted by the A / D conversion unit 4 is stored in the storage destination of the memory unit 5 designated by the memory address. The A / D converted digital data is stored in the memory unit 5 in synchronization with the signal and the horizontal synchronization signal. When the sampling frequency of the A / D conversion unit 4 is about 6 MHz, the horizontal synchronization interval and its front and rear are displayed. Except for this, data of about 300 pixels per horizontal scanning line can be obtained.
[0045]
At the time of capturing such image data, the control unit 9 recognizes the adjustment position of the density adjustment knob based on the signal from the density adjustment unit 6, and the A / D conversion unit 4 determines the adjustment position based on the adjustment position. Since the black and white level judgment of the video signal can be adjusted by raising and lowering the reference voltage used when converting the analog signal to the digital signal, the density of the captured image can be adjusted by the user's operation when capturing the image data. It can be adjusted arbitrarily.
[0046]
The reason why image data for 220 lines is captured is that one field of an NTSC video signal is composed of 525/2 = 262.5 scanning lines, but the time of 20 scanning lines as a vertical synchronizing signal section. Therefore, the actual video section is the remaining 242.5 scanning lines, and in order to prevent noise from occurring before and after the vertical synchronization section, 220 lines excluding the vertical synchronization section and the periods before and after the vertical synchronization section are included. Data is captured and stored in the memory unit 5 by using a horizontal scanning line of about a valid image area.
[0047]
When such image data has been captured for 220 lines (steps F11 and F12), “1” is added to the number of captured screens (step F13) to return to the standby state and the number of captured screens Display.
[0048]
  The display of the number of captured screens is performed by the control unit 9 controlling the display unit 12 to turn on the memory LED 12b. When one screen is not captured in the memory unit 5, the display unit 12 is always turned off. In the state of capturing one screen, 0.2 second ON / 1.5 second OFF blinks repeatedly. In the state of capturing two screens, 0.2 second ON / 0.4 second OFF / 0.2 second ON / 1. Repeated 5 seconds OFF, and 0.2 seconds ON / 04.4 when 3 screens are captured. Repeats OFF / 0.2 seconds ON / 0.4 seconds OFF / 0.2 seconds ON / 1.5 OFF, and when 4 screens are captured and no more data can be stored in the memory unit 5, the memory LED 12b is always turned on. It is to light up.
[0049]
  When the capture button is operated (step F1), the control unit 9 determines that the number of screens of image data stored in the memory unit 5 is greater than or equal to a predetermined number (step F2), and waits. By returning to the state and operating the cancel button 18 in this standby state (step F14), the last captured image can be erased from the memory unit 5 (steps F15 to F17). That is, when the cancel button 18 is pressed once in the state in which three screens of image data have been captured, the image data for the third screen in the memory unit 5 is erased, the state in which two screens have been captured, and the state in which these two screens have been captured. When the cancel button 18 is pressed once, the screen returns to the state where one screen has been captured, and when the cancel button 18 is pressed once again, all image data is erased. Even during such image data canceling operation, the number of captured screens is displayed by turning on and flashing the memory LED 12b.
[0050]
Therefore, according to the operation control, a user can store a desired video in the memory unit 5 and can easily check the number of screens of image data stored in the memory unit 5.
[0051]
Next, the operation control when performing facsimile transmission based on the image data stored in the memory unit 5 by the above operation control will be described.
[0052]
  First, as shown in FIG. 6, the terminal to which the image sensor 21 is connected and the facsimile connection terminal provided on the plane of the video signal converter are connected by a connection cable for video signal input. As shown in (b), the drive clock generated from the drive clock generator 23 is input to the video signal converter, and the image data output from the video signal converter is supplied to the read signal binarization processor 24. .
[0053]
Then, when the video signal conversion apparatus and the facsimile apparatus are connected by the connection cable for video signal input in this way, the video signal conversion apparatus and the facsimile apparatus are “VIDEO”, “φ1”, “ The pixel clock signals from the facsimile apparatus are connected by the signal lines of “φ1” and “φT”, among which the signal lines of “T”, “TxA”, “RxA”, “+ 5V”, and “GND” are connected. The line synchronization signal is supplied to the video signal converter, and power is supplied from the facsimile apparatus to the video signal converter via the “+ 5V” and “GND” signal lines, and the video is supplied via the “VIDEO” signal line. The video signal converted into the analog signal in the signal conversion device is supplied to the facsimile device, and “TxA” and “RxA” Route can send and receive a command signal to the two-way facsimile apparatus and a video signal conversion apparatus by, the command signals are transmitted and received as a serial signal of asynchronous method.
[0054]
  Of these signal lines, other than the “TxA” and “RxA” signal lines, “VIDEO”, “φ1”, “φT”, “+5 V”, and “GND” are set when the image sensor is connected. The same can be used, and power is supplied from the facsimile apparatus to the video signal conversion apparatus through the signal lines of “+5 V” and “GND”, and accordingly, the battery 13 built in the video signal conversion apparatus The battery 13 is prevented from being consumed by stopping the power supply.
[0055]
Further, the “RxA” signal line is connected to the ground (0 V) via a resistor (not shown) in the facsimile apparatus, while the video signal conversion apparatus is connected to the “RxA” signal line except when a command signal is being sent. By outputting a level (+5 V) signal, the facsimile apparatus detects the signal from the signal line “RxA” when the video signal converter is not connected as a ground level, and connects the video signal converter. In this case, the signal from the “RxA” signal line can be detected as a high level.
[0056]
Then, the main control unit 30 of the facsimile apparatus constantly monitors the signal level of the “RxA” signal line at a constant cycle, and detects that the signal level has changed from the ground level to the high level (step F31). Then, it is determined that the video signal converter is connected, and a confirmation command is output through the “TxA” signal line (step F32).
[0057]
When the confirmation command output through the “TxA” signal line is received by the video signal converter (step F21), the response command using the number of screens captured in the memory unit 5 in the control unit 9 as a parameter. Is output through the signal line “RxA” (step F22).
[0058]
When the response command output through the signal line “RxA” is received by the facsimile apparatus (step F33), the main control unit 30 of the facsimile apparatus captures the connection of the video signal conversion apparatus and the number of screen images. The main control unit 30 captures the predetermined data confirmed along with this (step F34) and cancels the shading correction in the read signal binarization processing unit 24 (step F35). .
[0059]
  The shading correction is performed by comparing with the reference document reading signal, so that when the image sensor 21 optically reduces the image with a lens and reads the document, the amount of light in the peripheral portion is smaller than that in the central portion. The reason for canceling such shading correction when a video signal converter is connected is that the output signal is not output to the input signal from the video signal converter. This is because there is no uniformity, and when shading correction is applied, the left and right images become brighter than the center.
[0060]
In this way, after the video signal conversion device is connected to the facsimile apparatus and predetermined data is taken in by the main control section 30 of the facsimile apparatus, the user should operate the operation section 29 of the facsimile apparatus for transmission. When an image is designated (step F36), the main control unit 30 stores the screen number of the designated image (step F37).
[0061]
Then, after designating an image to be transmitted by the user's operation, when the user performs a call operation by operating the operation unit 29 (step F38), the main control unit 30 responds to the call operation. Controls the communication unit 26 to DC-close the telephone line 25 and sends out the telephone number inputted to the DC-lined telephone line 25 by dial pulse or DTMF signal (step F39).
[0062]
Along with this, the exchange connected to the telephone line 25 detects this, calls the designated partner, and connects the user facsimile machine and the partner facsimile machine via the telephone line 25 when the partner facsimile machine responds. When the user facsimile apparatus and the partner facsimile apparatus are connected in this way, a facsimile signal (CED-DIS signal or the like) is sent from the partner facsimile apparatus (reception side), and this facsimile signal is transmitted to the user facsimile apparatus ( A sound signal is emitted as a sound signal from a speaker (not shown) provided in the communication unit 26 on the calling side, so that the user can confirm that the communication connection with the other party is established (step F40).
[0063]
Then, after confirming that the user has established communication connection with the counterpart facsimile machine, when the communication start instruction operation is performed by operating the operation unit 29 (step F41), the main control unit 30 performs the communication start instruction. Based on the operation, the number of lines of the transmission image data is set to “0” (step F42), and a transfer start command in which a transmission screen number stored in advance is designated as a parameter is transmitted to the video signal conversion device through the signal line “TxA”. Output (step F43).
[0064]
That is, for example, when a video signal conversion apparatus in which a four-screen image is captured is connected to the facsimile apparatus, it is recognized that the facsimile apparatus has a four-screen image by the transmission / reception operation of the confirmation command and the response command. Of these, when the operation of the operation unit 29 of the facsimile apparatus is instructed to transmit the images of the second screen and the fourth screen, in the facsimile apparatus, the main control unit 30 first starts based on the communication start instruction operation. The transfer start command designated by the parameter for the second screen is output to the video signal converter, and after the image of the second screen is transmitted by facsimile, the transfer start command designated by the parameter for the fourth screen is sent to the video signal converter. Send it.
[0065]
Then, after a transfer start command is output through the “TxA” signal line, when a predetermined time elapses (step F44), the main control unit 30 outputs a pixel clock and a line synchronization signal through the “φ1” and “φT” signal lines. In addition to outputting (steps F47 and F48), "1" is added to the number of lines of transmission image data (step F49), and the pixel clock and line synchronization are performed until the counted number of lines reaches a predetermined number (step F50). A signal is output.
[0066]
In the video signal converter, the line synchronization signal output through the “φT” signal line is detected, and the image signal transfer is started for each line in synchronization therewith. The signal may be always output through the “φ1” signal line.
[0067]
On the other hand, in the video signal conversion apparatus, when the transfer start command output through the “TxA” signal line is received (step F23), the control unit 9 designates the screen designated based on the received transfer start command. The number is recognized, the memory reading start address of the memory unit 5 in which the image data of the recognized screen number is taken is set (step F24), and the number of lines of the read image data is set to “0” (step F25).
[0068]
When the control unit 9 detects the line synchronization signal output through the “φT” signal line (step F26), the image data for one line is read from the memory unit 5 in accordance with a preset memory reading start address. The read image data for one line is output to the facsimile apparatus through the “VIDEO” signal line (step F26), and “1” is added to the number of lines of the read image data (step F27) and counted. Until the number of lines reaches a predetermined number (step F28), image data for one line is output based on the line synchronization signal output through the “φT” signal line.
[0069]
The image data output at this time reads out one line of image data from the memory unit 5 in accordance with a memory read start address set in advance by the control unit 9, and the read image data for one line is converted to D / A. The signal is converted into an analog signal by the conversion unit 10 and then sent to the signal output unit 11 and input to the read signal binarization processing unit 24 of the facsimile apparatus via a predetermined cable.
[0070]
On the other hand, in the facsimile apparatus, one line of image data output through the “VIDEO” signal line is binarized by the read signal binarization processing unit 24, and then the compression / decompression processing unit 27 performs MH encoding or the like. A facsimile transmission operation is performed by converting the facsimile code signal into a facsimile code signal and transmitting the converted facsimile code signal onto the telephone line 25 through the communication unit 26.
[0071]
When the transmission of image data for one screen is completed by such a facsimile transmission operation, the main control unit 30 checks whether there is a transmission screen number stored in advance (step F51), and determines that there is a next screen. Then, after setting the number of lines of transmission image data to “0”, a transfer start command designating the transmission screen number of the next screen as a parameter is output to the video signal conversion device through the “TxA” signal line ( The above-described operations such as steps F42 and F43) are repeated, and when it is determined that there is no next screen, the main control unit 30 performs a communication end operation using a predetermined communication protocol (step F52) and ends the facsimile transmission operation.
[0072]
By the way, in a facsimile transmission operation, in a mode generally called G3 facsimile communication, a complicated image tends to take a longer transmission time. For example, an image of 1728 pixels for one scanning line of A4 width and all white is displayed in ITU. When encoded with the standard one-dimensional encoding method stipulated in the recommendation T4 of -T, 29-bit code data “01001101100110101000000000001” is obtained. When this code data is transmitted at a transmission rate of 9600 bits / second, about 3 mm In an image in which white and black appear alternately every pixel, the code data for one A4 width scanning line is 7788 bits, and transmission takes about 811 milliseconds.
[0073]
Therefore, when the image data transferred from the video signal converter is transmitted by facsimile, if the image captured by the video signal converter is simple and has few black and white transition points, the amount of facsimile code is small and the video signal Although transmission can be performed faster than the speed input from the conversion device, when binarization processing is performed in a pseudo halftone mode such as the error diffusion method, black-and-white change points increase and the amount of facsimile code per line also increases. Therefore, since transmission takes time and a transmission buffer overflow occurs, it is necessary to temporarily interrupt the transfer of image data from the video signal converter.
[0074]
Therefore, in the facsimile apparatus, when the main control unit 30 monitors the remaining amount of the transmitted facsimile code (step F45) and determines that it is necessary to interrupt the input of the image data based on the remaining amount of the transmitted facsimile code. In (Step F46), the main control unit 30 performs control so as not to output the line synchronization signal. On the other hand, the video signal conversion apparatus transfers one line of image based on detection of the line synchronization signal output from the facsimile apparatus. Therefore, while the line synchronization signal is not detected, the image transfer of the next line is not started, and the input of the image data can be interrupted accordingly.
[0075]
Instead of temporarily stopping the output of the line synchronization signal and interrupting the image data transfer, the facsimile apparatus is provided with a memory for storing the image data for one screen, and the image data transferred data is stored in the memory. Thus, the transmission buffer overflow can also be prevented by executing the image data transfer without interruption.
[0076]
  Therefore, according to the above-described operation control, the video signal conversion apparatus storing a desired video in the memory unit 5 by the user is connected to the facsimile apparatus, and a predetermined call operation is performed, thereby the memory unit of the video signal conversion apparatus. The image data based on the video stored in 5 can be converted into facsimile data and transmitted to the other facsimile apparatus. At this time, a conventional apparatus portion for converting into facsimile data is used and an image sensor 21 is used. The read image data can be shared with the apparatus portion that converts the image data into facsimile data.
[0077]
When the image captured by the video signal converter is transmitted to the counterpart facsimile machine, the date / time information at that time is read from the clock built in the main control unit 30 for each transmission page, and is converted into a character pattern together with the transmission page number. By converting, adding the input video signal to the binarized image data, encoding the facsimile, and transmitting it, it is possible to indicate the date and time of transmission and the name of the sender that are usually added to the upper part of the original read image in the facsimile apparatus. The transmission source information may be added when an image captured by the video signal converter is transmitted.
[0078]
Next, the operation control when copying based on the image data stored in the memory unit 5 by the operation control will be described.
[0079]
In the same manner as in the facsimile transmission operation described above, after connecting the video signal conversion device and the facsimile device with the connection cable for video signal input, the facsimile device specifies the screen number of the screen to be copied and performs the copy output operation. Then, a transfer start command designating the designated screen number as a parameter is outputted from the facsimile apparatus, and a pixel clock and a line synchronization signal are outputted.
[0080]
On the other hand, when the line synchronization signal is detected in the video signal converter, the control unit 9 of the video signal converter uses one line's worth based on the readout start address of the screen number designated by the transfer start command from the memory unit 5. The image data is read, and the read image data for one line is converted into an analog signal by the D / A converter 10 and output to the read signal binarization processor 24 of the facsimile apparatus via the signal output unit 11.
[0081]
In the facsimile apparatus, the data binarized by the read signal binarization processing unit 24 is sent to the recording unit 28 via the compression / decompression processing unit 27, and the recording unit 28 outputs an image based on the input data to a predetermined value. Print out on the original paper.
[0082]
At the time of this printout, the recording output speed is constant, and it is not necessary to perform control such as interrupting the line synchronization signal and stopping the transfer during the printout. However, since the facsimile apparatus performs such interruption / resumption control of the transfer, there is no need to identify transmission / copy in the video signal conversion apparatus, and image data according to a command and a synchronization signal sent from the facsimile apparatus. Should be output.
[0083]
  Therefore, according to the above-described operation control, the video signal conversion apparatus storing a desired video in the memory unit 5 by the user is connected to the facsimile apparatus and a predetermined copy operation is performed, whereby the memory unit 5 of the video signal conversion apparatus. The image data based on the video stored in the image data can be printed out on a predetermined sheet. At this time, the image data read by the image sensor 21 is used by using a conventional device portion for converting to copy data. It can be used in common with the device portion for converting to copy data.
[0084]
Even in such a copying operation, the date and time information at that time is read from the clock built in the main control unit 30 and converted into a character pattern together with the transmission page number, as in the facsimile transmission operation described above, and the input video By adding the signal to the binarized image data and printing it out, it is possible to reliably arrange the printed sheets.
[0085]
Further, such a copying operation may be incorporated into a video signal capturing operation or a facsimile transmission operation.
In other words, when the copy operation is incorporated into the video signal capture operation, the video signal output device connected by a predetermined wired cord is connected to the facsimile device by a video signal input connection cord. When the video signal conversion device completes capturing the video signal from the video signal output device, the video signal conversion device sends a response command with the number of new captured screens as a parameter to the facsimile device. When a response command is received and it is recognized that a new image has been captured, control may be performed so that the newly captured image is copied and output.
[0086]
In addition, when the copy operation is incorporated into the facsimile transmission operation, after confirming the image captured in the video signal converter by copying, the telephone is transmitted without changing the transmission screen number (copy screen number). By performing the start instruction operation, the same image as the copy output can be transmitted in the same order. Similarly, when sending the same image to a plurality of other parties, the transmission operation may be sequentially performed without changing the transmission screen number.
[0087]
  Next, another embodiment of the present invention will be described in detail with reference to FIG. In FIG. 13, parts common to FIG. 1 are denoted by common reference numerals.
[0088]
Reference numeral 31 denotes a compression / decompression processing unit that compresses the data digitally converted by the A / D conversion unit 4 using the DPCM method and the like, and decompresses the compressed data read from the memory unit 5. Reference numeral 32 denotes a compression / decompression processing unit 31. And an enlargement processing unit for enlarging the processed data image.
[0089]
A video signal capturing operation in the video signal converter configured as described above will be described.
When the video signal converter is in a standby state due to the connection between the video signal output device that is outputting the video signal and the video signal converter that is turned on, the user is provided with the mounting provided on the upper surface of the device body. When the capture instruction button is operated, an image capture signal is output from the capture instruction section 7 in response to the operation of the capture instruction button, and the control section 9 responds to the image capture instruction signal with the memory section It is determined whether the number of screens of image data stored in 5 is a predetermined number (four screens in this embodiment) or more.
[0090]
At this time, if it is determined that the number of screens of the image data stored in the memory unit 5 is equal to or less than the predetermined number, after the control unit 9 detects the vertical synchronization signal separated by the video signal processing unit 3 Each time the horizontal synchronizing signal separated by the video signal processing unit 3 is detected and then the horizontal synchronizing signal is detected 11 times in the control unit 9 and then the horizontal synchronizing signal is detected in the control unit 9. One line of image data is captured, and a total of 220 lines of image data are captured.
[0091]
The one-line image data is captured by converting the luminance signal, which is an analog signal, into 8-bit digital data per pixel in the A / D conversion unit 4, and then converting the 8-bit digital data by the data compression / decompression unit 31. In addition to the compression to 4-bit digital data, the control unit 9 sequentially generates a memory address of the storage destination based on the vertical synchronization signal and the horizontal synchronization signal, and the data is compressed to the storage destination of the memory unit 5 designated by the memory address By storing the digital data compressed by the decompression unit 31, the digital data is stored in the memory unit 5 in synchronization with the vertical synchronization signal and the horizontal synchronization signal.
[0092]
Therefore, according to the operation control, a user can store a desired video in the memory unit 5 and can suppress the data amount of image data stored in the memory unit 5.
[0093]
The operation control for facsimile transmission based on the image data stored in the memory unit 5 by the operation control and the operation control for the copy operation are the same as those in the above embodiment. The processing operation of image data transferred from the conversion device to the facsimile device, the number of lines of image data transferred in the video signal conversion device, and the number of lines of image data transmitted in the facsimile device will be described below.
[0094]
In the same manner as in the above embodiment, the video signal conversion device and the facsimile device are connected by the connection cable for video signal input, and after the screen number of the screen to be transmitted or copied is designated, a transmission or copy start instruction is made. When a transfer start command designating a screen number designated by a facsimile device as a parameter is output and a pixel clock and a line synchronization signal are output, the video signal converter detects the line synchronization signal. Then, the control unit 9 of the video signal converter reads the image data for one line from the memory unit 5 based on the reading start address of the screen number designated by the transfer start command, and compresses the read image data for one line. After the decompression processing unit 31 decompresses the original data, the enlargement processing unit 32 performs image enlargement processing. Is performed with the data subjected to the image enlargement processing is converted into an analog signal by the D / A converter 10, it is outputted through the signal output unit 11 to the read signal binarizing section 24 of the facsimile apparatus.
[0095]
The reason why the image enlargement process is performed at the time of data transfer is that the number of pixels of the image stored in the memory unit 5 constituting the video signal converter is about 300 pixels in the horizontal direction and about 220 pixels in the vertical direction. If the image is converted into a facsimile signal on a one-to-one basis and transmitted at a resolution called fine mode, or printed out, the image size will be very small, about 37.5 mm × 28.6 mm, and it will be difficult to see. As a method, the original data may be simply repeated a plurality of times in the horizontal and vertical directions, or output data may be created by calculation from four neighboring data using a projection method. The image is output to the facsimile machine on a one-to-one basis without being enlarged, and the enlargement process is performed on the facsimile machine side. Good.
[0096]
In the facsimile apparatus, the data binarized by the read signal binarization processing unit 24 is converted into facsimile data such as an MH code by the compression / decompression processing unit 27 and transmitted on the telephone line 25 or in the recording unit 28. Print out.
[0097]
At this time, the number of lines of image data to be transmitted or printed out depends on the enlargement process on the image enlargement unit 32 or the facsimile apparatus side of the video signal converter, and accordingly, the facsimile apparatus changes to the video signal converter. The number of transfer times of the line synchronization signal to be output and the image data output from the video signal converter to the facsimile machine are different.
[0098]
Therefore, according to the above-described operation control, the image data compressed and stored in order to suppress the data amount of the image data stored in the memory unit 5 can be output as the image data before compression, and the transfer image data When the image is transmitted by facsimile or printed out, the image size can be set appropriately.
[0099]
In this embodiment, the video signal conversion apparatus and the video signal output apparatus are connected by a predetermined wired cord, and the video signal conversion apparatus is configured by using the video signal obtained from the video signal output apparatus as predetermined image data. After storing in the memory unit 5, the video signal conversion device and the image data processing device (facsimile device in this embodiment) are connected, and the memory constituting the video signal conversion device in response to the transfer clock from the image data processing device However, the present invention is not limited to this. For example, as shown in FIG. 8, a video signal output device and image data are connected to a video signal conversion device. The image data may be transferred by connecting the image processing device to the processing device with a predetermined wired cord, and the video signal conversion device may be incorporated in the image data processing device. It may be configured to.
[0100]
【The invention's effect】
  As described above, according to the present invention, image data using the captured video signal is acquired by capturing the externally input video signal and outputting the captured video signal in synchronization with an arbitrary transfer clock. Since image data can be transferred according to the processing device, video signals can be transferred to a plurality of image data processing devices each having a different data processing speed, and the previously provided image processing circuit portion is used. can do. Further, since the control means returns to a standby state when the number of screens of data stored in the storage means exceeds a predetermined number, the data is prevented from being interrupted in the middle of one screen when data is output.
[0101]
  In addition, according to the present invention, image data processing for processing an image read by the image sensor by capturing an externally input video signal and outputting the captured video signal in synchronization with the drive clock of the image sensor. Since the captured video signal can be processed without increasing the processing circuit in the apparatus, the video signal can be processed without increasing the circuit scale and increasing the cost in the image data processing apparatus. .
[0102]
  Further, according to the present invention, when an externally input video signal is captured and the captured video signal is output in synchronization with an arbitrary transfer clock, the transfer of the image data is temporarily performed when the transfer clock is paused. Since the image data can be transferred in accordance with the processing speed of the output image data processing apparatus, the overflow in the image data processing apparatus can be prevented.
[0103]
  Furthermore, according to the present invention, since any video signal designated by the user can be surely captured by capturing an externally input video signal based on an operation by the user, a mistake in capturing the video signal, etc. Can be prevented.
[0104]
  Furthermore, according to the present invention, when an externally input video signal is captured and the captured video signal is output in synchronization with an arbitrary transfer clock, the captured video signal is used by performing an enlargement process. Since the size of the image can be adjusted according to the image data processing device, the size of the image to be displayed can be appropriately set for a plurality of image data processing devices each having a different screen or print resolution. .
[0105]
  Furthermore, according to the present invention, the externally input video signal is compressed and captured, and the captured video signal is expanded and output in synchronization with an arbitrary transfer clock. Since the capacity of the video signal to be captured can be reduced without changing it, more video signals can be captured, and the capacity of the memory for capturing video signals can be reduced, thereby contributing to cost reduction. can do.
[0106]
  Furthermore, according to the present invention, the video signal output from the video signal converter can be binarized using the binarization processing unit that binarizes the image data read by the image sensor. Since an image based on the video signal can be transmitted or copied without separately providing a circuit for processing the video signal, the transmission of the video signal or the increase in the circuit scale and cost in the facsimile apparatus can be avoided. You can make a copy. Further, since the control means returns to a standby state when the number of screens of data stored in the storage means exceeds a predetermined number, the data is prevented from being interrupted in the middle of one screen when data is output.
[0107]
  Furthermore, according to the present invention, since the connection part of the image sensor and the connection part of the video signal conversion part are made common, it is possible to save space in the facsimile apparatus, which contributes to improvement in design. it can.
[Brief description of the drawings]
FIG. 1 is a schematic functional block diagram showing an electrical configuration of a video signal converter according to an embodiment of the present invention.
FIG. 2 is an explanatory diagram showing a configuration of the video signal conversion apparatus.
FIG. 3 is a schematic functional block diagram showing an electrical configuration of a facsimile apparatus to which the video signal conversion apparatus can be connected.
FIG. 4 is an external perspective view illustrating a configuration in a state where an image sensor is mounted in the facsimile apparatus.
FIG. 5 is an external perspective view showing the configuration of the facsimile apparatus with an image sensor removed.
FIG. 6 is an external perspective view showing a configuration in which the video signal converter is connected in the facsimile apparatus.
FIG. 7 is an explanatory diagram showing a connection example between the video signal conversion apparatus and another apparatus.
FIG. 8 is an explanatory diagram showing an example of connection between the video signal conversion apparatus and another apparatus.
FIG. 9 is an explanatory diagram showing a list of signal lines connecting the video signal conversion apparatus and the facsimile apparatus.
FIG. 10 is a flowchart showing a video signal capturing operation in the video signal converter.
FIG. 11 is a flowchart showing an image data transfer operation in the video signal converter.
FIG. 12 is a flowchart showing a facsimile transmission operation in a facsimile machine to which the video signal converter is connected.
FIG. 13 is a schematic functional block diagram showing an electrical configuration of a video signal conversion apparatus according to another embodiment of the present invention.
FIG. 14 is a schematic functional block diagram showing an electrical configuration of a conventional facsimile apparatus.
[Explanation of symbols]
  1 Video signal input section
  2 Monitor signal output section
  3 Video signal processor
  4 A / D converter
  5 Memory part
  6 Density adjustment unit
  7 Capture instruction section
  8 Transfer clock input section
  9 Control unit
  10 D / A converter
  11 Signal output section
  21 Image sensor
  23 Drive clock generator
  24 Binarization processing section
  26 Communication Department
  27 Compression / decompression processor
  28 Recording section
  29 Operation unit
  30 Main control unit

Claims (8)

Video signal processing means for separating the synchronization signal and the luminance signal from the video signal externally input by the first device ;
A / D conversion means for converting the luminance signal separated by the video signal processing means into a digital signal;
Storage means for storing the digital signal converted by the A / D conversion means;
D / A conversion means for converting a digital signal read from the storage means into an analog signal;
External output means for outputting the luminance signal converted into an analog signal by the D / A conversion means to the outside;
The storage means stores the luminance signal from the first device converted into a digital signal by the A / D conversion means in synchronization with the synchronization signal separated by the video signal processing means, and stores it in the storage means. Control means for returning to a standby state when the number of data screens exceeds a predetermined number , and for reading out the luminance signal stored in the storage means in synchronization with a transfer clock externally input from the second device ; A video signal conversion device comprising: The external input transfer clock is a drive clock for driving an image sensor that reads image data from a document,
2. The video signal converter according to claim 1, wherein the external output means outputs the analog signal converted by the D / A conversion means to the outside as an output signal of the image sensor. The control means, when resting external transfer clock temporary before data read completion of the storage means, the image of claim 1 or 2, wherein the temporarily suspends data reading by the memory means Signal converter. Provide operation input means to instruct external input video signal capture,
The control means causes the data storage by the storage means to be performed in synchronization with the synchronization signal separated by the video signal processing means when a capture instruction is made by the operation input means. The video signal converter according to any one of 1 to 3.   5. The video signal conversion apparatus according to claim 1, further comprising an enlargement processing unit that performs an enlargement process on the digital signal read from the storage unit. Data compression means for compressing data of the digital signal converted by the A / D conversion means;
Data decompression means for decompressing the digital signal compressed by the data compression means into a base signal;
6. The storage device according to claim 1, wherein the storage means stores the digital signal compressed by the data compression means and decompresses the read digital signal by the data decompression means. The video signal converter described in 1. The video signal converter according to any one of claims 2 to 6,
Drive clock generating means for generating a drive clock for driving the image sensor;
And binarization processing means for binarizing the image data read by the image sensor,
The drive clock generation means outputs the generated drive clock as a transfer clock to the video signal converter,
The facsimile apparatus, wherein the binarization processing means binarizes the output signal output from the video signal converter. Facsimile apparatus according to claim 7, characterized in that it comprises a facsimile apparatus having a connecting portion to the upper Symbol image sensor and the video signal conversion device can be selectively connected.

Images