JP6778390B2 - Data receiving device, exposure device and image forming device - Google Patents

Description

The present invention relates to a data receiving device, an exposure device, and an image forming device.

In Patent Document 1, a fixed image pattern is generated in a self-diagnosis mode in which a self-diagnosis of an edge enhancement portion is performed, and the generated fixed image pattern is input as an input signal so that a faulty part can be determined. The image processing apparatus is disclosed.

Patent Document 2 provides a correction means for correcting the frequency characteristic of the differential signal line, which has a peaking characteristic in a high frequency region in the frequency characteristic of the differential signal line at the terminal portion of the differential signal line. The image reader is disclosed.

Japanese Unexamined Patent Publication No. 7-58949 Japanese Unexamined Patent Publication No. 2005-72976

In a transmission system that transmits image data via a differential transmission line, when a non-shield type low-cost transmission line harness or the like is used for the differential transmission line, the characteristic impedance of the differential transmission line depends on the routing condition of the harness. Will change.

Then, when the characteristic impedance of the differential transmission line changes, there is a difference between the pixel size of the first pixel after the same potential continues for a preset time or longer and the pixel size of the pixel after the first pixel. It may occur. As a result, there may be a problem that the reproducibility of the edge portion, the thin line, or the like of the image transmitted via the differential transmission line is deteriorated.

An object of the present invention is the pixel size of the first pixel after the same potential continues for a preset time or longer when transmitting image data via a differential transmission line, and the pixel size after the first pixel. It is an object of the present invention to provide a data receiving device, an exposure device, and an image forming device capable of reducing a difference between a pixel and a pixel size.

[Data receiver]
The present invention according to claim 1 comprises a receiving means for receiving image data transmitted via a differential transmission line.
A comparison means for comparing the pixel size of the first pixel of the image data received by the receiving means after the same potential continues for a preset time or longer and the pixel after the first pixel.
An adjusting means for adjusting the resistance value of the terminating resistance of the differential transmission line based on the comparison result in the comparing means is provided .
The comparison means
A measuring means for measuring the high-level period of the first pixel after the same potential continues for a preset time or longer and the high-level period of the pixel after the first pixel.
A calculation means for calculating the ratio of two periods measured by the measurement means is provided.
It is a data receiving device.

According to the second aspect of the present invention, when the adjusting means has a pixel size of the first pixel smaller than the pixel size of a pixel after the first pixel in the comparison result of the comparing means, the termination is performed. The data receiving device according to claim 1, wherein the resistance value of the resistor is adjusted so as to be small.

The data receiving device according to claim 1, wherein the adjusting means adjusts the resistance value of the terminating resistor of the differential transmission line within a predetermined time after the power is turned on. Is.

According to a fourth aspect of the present invention, the adjusting means adjusts the resistance value of the terminating resistance of the differential transmission line when a component that may change the state of the differential transmission line is replaced. The data receiving device according to 1 or 2.

The present invention according to claim 5, wherein the measuring means, the duration of the high level of each pixel, a data receiving apparatus according to claim 1, wherein measuring the number of clocks of the reference clock.

The present invention according to claim 6, wherein the measuring means, by converting into a voltage corresponding to the high-level period of each pixel, the data receiving apparatus according to claim 1, wherein measuring the period of the high level of each pixel is there.

[Exposure device]
The present invention according to claim 7 comprises a receiving means for receiving image data transmitted via a differential transmission line and a receiving means.
A comparison means for comparing the pixel size of the first pixel of the image data received by the receiving means after the same potential continues for a preset time or longer and the pixel after the first pixel.
An adjusting means for adjusting the resistance value of the terminating resistance of the differential transmission line based on the comparison result in the comparing means, and
A control means for controlling the light emitted to the photoconductor based on the image data received by the receiving means is provided .
The comparison means
A measuring means for measuring the high-level period of the first pixel after the same potential continues for a preset time or longer and the high-level period of the pixel after the first pixel.
A calculation means for calculating the ratio of two periods measured by the measurement means is provided.
It is an exposure device.

[Image forming device]
The present invention according to claim 8 is a receiving means for receiving image data transmitted via a differential transmission line, and a receiving means.
A comparison means for comparing the pixel size of the first pixel of the image data received by the receiving means after the same potential continues for a preset time or longer and the pixel after the first pixel.
An adjusting means for adjusting the resistance value of the terminating resistance of the differential transmission line based on the comparison result in the comparing means, and
A control means for controlling the light emitted to the photoconductor based on the image data received by the receiving means, and
It is provided with an output means for outputting an image obtained by developing a latent image formed on the photoconductor by the light controlled by the control means on a recording medium.
The comparison means
A measuring means for measuring the high-level period of the first pixel after the same potential continues for a preset time or longer and the high-level period of the pixel after the first pixel.
A calculation means for calculating the ratio of two periods measured by the measurement means is provided.
It is an image forming apparatus.

According to the present invention according to claim 1, the image data is set in advance when the image data is transmitted through the differential transmission line, as compared with the case where the resistance value of the terminating resistance of the differential transmission line is set to a fixed value. It is possible to provide a data receiving device capable of reducing the difference between the pixel size of the first pixel after the same potential continues for a certain period of time or more and the pixel size of the pixel after the first pixel.

According to the present invention according to claim 2, the image data is set in advance when the image data is transmitted via the differential transmission line, as compared with the case where the resistance value of the terminating resistance of the differential transmission line is set to a fixed value. It is possible to provide a data receiving device capable of reducing the difference between the pixel size of the first pixel after the same potential continues for a certain period of time or more and the pixel size of the pixel after the first pixel.

According to the third aspect of the present invention, even if the state of the differential transmission line changes while the power is turned off, the pixel size of the first pixel after the same potential continues for a preset time or longer, and this. It is possible to provide a data receiving device capable of reducing the difference from the pixel size of the pixel after the first pixel.

According to the fourth aspect of the present invention, even when a component that may change the state of the differential transmission line is replaced, the pixel size of the first pixel after the same potential continues for a preset time or longer It is possible to provide a data receiving device capable of reducing the difference from the pixel size of the pixel after the first pixel.

According to the present invention according to claim 5 , the image data is set in advance when the image data is transmitted through the differential transmission line, as compared with the case where the resistance value of the terminating resistance of the differential transmission line is set to a fixed value. It is possible to provide a data receiving device capable of reducing the difference between the pixel size of the first pixel after the same potential continues for a certain period of time or more and the pixel size of the pixel after the first pixel.

According to the present invention according to claim 6 , the image data is set in advance when the image data is transmitted through the differential transmission line, as compared with the case where the resistance value of the terminating resistance of the differential transmission line is set to a fixed value. It is possible to provide a data receiving device capable of reducing the difference between the pixel size of the first pixel after the same potential continues for a certain period of time or more and the pixel size of the pixel after the first pixel.

According to the present invention according to claim 7 , the image data is set in advance when the image data is transmitted through the differential transmission line, as compared with the case where the resistance value of the terminating resistance of the differential transmission line is set to a fixed value. It is possible to provide an exposure apparatus capable of reducing the difference between the pixel size of the first pixel after the same potential continues for a certain period of time or longer and the pixel size of the pixel after the first pixel.

According to the present invention according to claim 8 , the image data is set in advance when the image data is transmitted via the differential transmission line, as compared with the case where the resistance value of the terminal resistance of the differential transmission line is set to a fixed value. It is possible to provide an image forming apparatus capable of reducing the difference between the pixel size of the first pixel after the same potential continues for a certain period of time or more and the pixel size of the pixel after the first pixel.

It is a figure which shows the structure of the image formation system of one Embodiment of this invention. It is the schematic sectional drawing of the image forming apparatus 10 of one Embodiment of this invention. It is a figure which shows the state that the exposure apparatus 27 and the image processing apparatus 50 are connected by a differential transmission line 60. It is a figure for demonstrating the state when the image data is transmitted by the differential transmission line 60 between an image processing apparatus 50 and an exposure apparatus 27. It is a figure for demonstrating the state when the image data is transmitted by the differential transmission line 60 between an image processing apparatus 50 and an exposure apparatus 27. It is a figure for demonstrating how image data is transmitted when the resistance value of a terminating resistor 70 is set to a fixed value. When high-level image data of a plurality of pixels is transmitted via the differential transmission line 60 for the same period, the first pixel 101 is compared with the subsequent second pixels 102 and 103 for a high-level period. It is a figure for demonstrating how is shortened. It is a figure for demonstrating the state when the thin line image of 1 pixel width is transmitted through the differential transmission line 60. It is a block diagram for demonstrating the structure of the image processing apparatus 50 and the exposure apparatus 27 in one Embodiment of this invention. It is a figure for demonstrating the area used when the adjustment process of the resistance value of a terminating resistor 70 is executed by the test data generated in the image processing apparatus 50. It is a block diagram for demonstrating the structure of the pixel size comparison part 64 shown in FIG. It is a block diagram for demonstrating the structure of the pixel high level period measurement unit 71. It is a figure for demonstrating how the pixel high level period measuring unit 71 measures the high level period of each pixel. It is a block diagram which shows the structure of the pixel high level period measuring part 71a which measures the high level period of each pixel in an analog manner. It is a figure for demonstrating the detailed structure of the terminating resistor 70. It is a figure which shows the waveform example of the image data after the resistance value of the terminating resistor 70 is adjusted.

Next, an embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram showing a configuration of an image forming system according to an embodiment of the present invention.

As shown in FIG. 1, the image forming system of one embodiment of the present invention is composed of an image forming device 10 and a terminal device 20 interconnected by a network 30. The terminal device 20 generates print data and transmits the print data generated via the network 30 to the image forming device 10. The image forming apparatus 10 receives the print data transmitted from the terminal apparatus 20 and outputs an image corresponding to the print data on the paper. The image forming apparatus 10 is a so-called multifunction device having a plurality of functions such as a printing (printing) function, a scanning function, a copying (copying) function, and a facsimile function.

Next, FIG. 2 shows a schematic cross-sectional view of the image forming apparatus 10 of the present embodiment shown in FIG. The image forming apparatus 10 includes a UI device 12, an image forming apparatus main body 14, and an image reading device 16.

The UI device 12 is a device including a display device for displaying information and an input receiving device for receiving input made by an operator, and is composed of, for example, a touch panel or the like. The operator can input the operation setting information via the UI device 12.

The image forming apparatus main body 14 has, for example, a three-stage recording medium supply cassette 18, and each of these recording medium supply cassettes 18 is provided with a supply head 21.

When one of the recording medium supply cassettes 18 is selected, the supply head 21 operates to supply the selected recording medium supply cassette 18 to the image forming unit 24 via the recording medium supply path 22.

The image forming unit 24 is provided with a photoconductor 26 of each color of yellow, magenta, cyan, and black, and is provided with an intermediate transfer belt 28.

In addition to the exposure device 27 and the developing device 29, a charging device, a primary transfer device, a cleaning device, and the like (not shown) are arranged around each photoconductor 26, and a toner image formed on each photoconductor 26 is displayed. It is transferred to the intermediate transfer belt 28. The exposure device 27 is composed of an LED and a laser light emitting device, and exposes each photoconductor 26 to form an electrostatic latent image. Then, the electrostatic latent image formed on each photoconductor 26 is developed as a toner image by the developing device 29, and transferred onto the intermediate transfer belt 28.

The toner image on the intermediate transfer belt 28 is transferred to the transmitted recording medium by the secondary transfer roll 31 and fixed by the fixing device 32, and the recording medium on which the toner image is fixed passes through the recording medium discharge path 34. It passes through and is discharged to the discharge unit 36.

The image reading device 16 includes a document supply unit 42 to which the document is supplied, a document image reading unit 43 for reading the image of the document, a document feeding device 44 for feeding the document from the document supply unit 42 to the image reading unit 43, and a document. It is provided with a document ejection unit 45 for ejecting a document whose image has been read by the image scanning unit 43.

Further, the image forming apparatus main body 14 is provided with an image processing apparatus 50. The image processing device 50 performs image processing of the image data transmitted from the terminal device 20 and the like and the image data read by the image reading unit 43.

It should be noted that the image obtained by developing the latent image formed on the photoconductor 26 by the light emitted from the exposure device 27 by the constituent members such as the developing device 29 and the charging device described above is displayed on the recording medium. An output means for outputting to is configured.

The exposure apparatus 27 described above receives image data from the image processing apparatus 50 and controls the light emitted to the photoconductor 26 based on the received image data.

Then, the exposure apparatus 27 and the image processing apparatus 50 are connected by a differential transmission line 60 as shown in FIG. The differential transmission line 60 transmits image data by a differential transmission method that transmits data based on a voltage difference between two transmission lines.

In this embodiment, a non-shield type low-cost transmission line harness or the like is used for the differential transmission line 60. Therefore, the characteristic impedance of the transmission line may change due to a change in the routing condition of the transmission line harness.

For example, in the case shown in FIG. 3A and the case shown in FIG. 3B, the harness state of the differential transmission line 60 has changed, so that the characteristic impedance may have changed. There is.

When the units of the image processing device 50 and the exposure device 27 are replaced in the market, the harness state of the differential transmission line 60 may change from the initial state. Therefore, the characteristic impedance of the differential transmission line 60 may change from the value at the time when the image forming apparatus 10 is shipped.

A state in which image data is transmitted between the image processing device 50 and the exposure device 27 by the differential transmission line 60 will be described with reference to FIGS. 4 and 5.

As shown in FIG. 4, in the image processing device 50 that transmits image data, the image data transmission unit 51 converts the image data into a differential signal and transmits the image data to the differential transmission line 60. Then, the exposure apparatus 27 receives the differential signal transmitted via the differential transmission line 60 by the image data receiving unit 61, converts it into image data, and transfers it to another circuit in the exposure apparatus 27. There is.

The differential transmission line 60 is composed of two transmission lines P (positive) and N (negative), and image data is transmitted by a voltage difference between the two transmission lines.

A terminating resistor 70 for terminating the differential transmission line 60 is provided in the exposure apparatus 27. The voltage between the two transmission lines of the differential transmission line 60 is determined by the value of the terminating resistor 70. For example, in the LVDS (Low Voltage Differential Signal) standard, which is one of the low voltage differential standards, The terminating resistance is specified as 100Ω.

Further, in a high-speed data transmission / reception system, impedance matching is required between transmission / reception. In general, in a distributed constant line such as the differential transmission line 60, when the inductance component of the transmission line is L and the capacitance component is C, the characteristic impedance Z ₀ is (L /) as shown in FIG. C) Expressed as ^1/2 .

Here, when the impedance of the image data transmitting unit 51 is Z ₀₁ , the characteristic impedance of the differential transmission line 60 is Z _02, and the impedance of the image data receiving unit 61 is Z ₀₃ , then Z ₀₁ ≈ Z ₀₂ ≈ Z ₀₃ Ideally.

However, as shown in FIG. 5, components such as parasitic capacitances C1 to C3 and inductance components L1 and L2 are generated in the differential transmission line 60. Then, due to the change in the harness state of the differential transmission line 60 as shown in FIG. 3, the values of the parasitic capacitances C1 to C3, the inductance components L1 and L2, etc. generated in the differential transmission line 60 change. To do.

As a result, when the harness state of the differential transmission line 60 changes, the characteristic impedance Z ₀₂ of the differential transmission line 60 changes, and Z ₀₁ ≠ Z ₀₂ ≠ Z ₀₃ may occur. It will end up.

Even in such a case, the impedance in the image data transmission unit 51 and the image data reception unit 61 is designed to be a standard value and does not change depending on the harness state of the differential transmission line 60. Therefore, Z ₀₁ ≈ Z _{It is 03} .

Then, when such an impedance mismatch occurs, there is a possibility that a defect may occur in the image data transmitted via the differential transmission line 60.

In this embodiment, the influence of a defect caused by impedance mismatch is reduced by changing the resistance value of the terminating resistor 70, but image data is obtained when the resistance value of the terminating resistor 70 is set to a fixed value. Will be described with reference to FIG.

In FIG. 6, when the input signal of the image data transmission unit 51 is transmitted to the image data reception unit 61 via the differential transmission line 60, the first pixel after the same potential continues for a preset time or longer. And, the pixel size of the pixel after this first pixel is different. This is because the eye pattern of the first pixel in the differential transmission line 60 is different from the eye pattern of the second and subsequent pixels.

Such a phenomenon occurs when the potential of the transmission line of the differential transmission line 60 has been constant for a while, but when the polarity is switched to the opposite potential, the potential is frequently switched. This is because it takes more time than.

That is, as shown in FIG. 5, parasitic capacitances C1 to C3 are generated on each transmission line of the differential transmission line 60, and when the same potential continues for a while, the parasitic capacitances C1 to C3 are charged. This is because it takes time to discharge the charged charge or, conversely, to recharge the parasitic capacitances C1 to C3 in a completely empty state.

As a result, as shown in FIG. 7, even when high-level image data of a plurality of pixels is transmitted via the differential transmission line 60 for the same period, the first first pixel 101 after the low-level period for a while. Compared with the subsequent second pixels 102 and 103, the high level period becomes shorter and the pixel size becomes smaller.

Therefore, when the terminating resistor 70 is set to a fixed value, for example, when a thin line image having a pixel width as shown in FIG. 8A is transmitted via the differential transmission line 60, it is shown in FIG. 8B. As a result, there is a problem that the thin line image becomes even thinner.

Next, the configuration of the present embodiment for reducing the influence of the problem as described above will be described with reference to FIG.

Also in FIG. 9, the image data from the image processing device 50 is transmitted to the exposure device 27, which is a data receiving device, via the differential transmission line 60.

As shown in FIG. 9, the image processing device 50 includes an image data transmission unit 51 and a control unit 52 that controls the operation of the image data transmission unit 51.

As shown in FIG. 9, the exposure apparatus 27 includes an image data receiving unit 61, an exposure apparatus control unit 62, an irradiation light control unit 63, a pixel size comparison unit 64, a terminating resistance adjusting unit 65, and a terminating resistor 70. It is composed of and.

The exposure apparatus control unit 62 adjusts the timing of transmitting image data to and from the control unit 52 of the image processing apparatus 50, and controls the operation of the image data receiving unit 61.

The image data receiving unit 61 receives the image data transmitted from the image data transmitting unit 51 via the differential transmission line 60.

The irradiation light control unit 63 controls the light to be applied to the photoconductor 26 based on the image data received by the image data receiving unit 61.

The pixel size comparison unit 64 is the pixel size of the first pixel of the image data received by the image data receiving unit 61 after the same potential continues for a preset time or longer, and the pixel size of the pixel after the first pixel. To compare.

The terminating resistance adjusting unit 65 adjusts the resistance value of the terminating resistor 70 of the differential transmission line 60 based on the comparison result in the pixel size comparing unit 64. Specifically, when the pixel size of the first pixel is smaller than the pixel size of the pixel after the first pixel in the comparison result in the pixel size comparison unit 64, the terminating resistance adjusting unit 65 has a terminating resistance 70. Adjust so that the resistance value of is small.

The terminating resistance adjusting unit 65 does not always adjust the resistance value of the terminating resistor 70 while the image data is being transmitted on the differential transmission line 60.

For example, the terminating resistor adjusting unit 65 adjusts the resistance value of the terminating resistor 70 of the differential transmission line 60 within a predetermined time after the power is turned on.

Alternatively, the terminating resistance adjusting unit 65 adjusts the resistance value of the terminating resistance 70 of the differential transmission line 60 when a component that may change the wiring state of the differential transmission line 60 is replaced. For example, the image processing device 50 and the exposure device 27 are configured as replaceable units, and when the units of the image processing device 50 and the exposure device 27 are replaced, or in the surroundings where the differential transmission line 60 is arranged. When the parts are replaced, the terminating resistance adjusting unit 65 can adjust the resistance value of the terminating resistance 70.

When the resistance value of the terminating resistor 70 is adjusted due to the replacement of parts that may change the wiring state of the differential transmission line 60 or the power being turned on, the image processing apparatus 50 may use the image processing device 50. Generates image data as test data in which white pixels (off pixels) are continuous for a preset number of pixels and then black pixels (on pixels) are continuous.

Then, the exposure apparatus 27 executes the adjustment processing of the resistance value of the terminating resistor 70 by receiving the test data generated by the image processing apparatus 50.

At this time, as shown in FIG. 10, the adjustment process of the terminating resistor 70 is executed using the outside of the image area in the exposure area.

Next, the configuration of the pixel size comparison unit 64 shown in FIG. 9 will be described with reference to the block diagram of FIG.

As shown in FIG. 11, the pixel size comparison unit 64 includes a pixel high level period measurement unit 71, a measurement result holding unit 72, and a high level period ratio calculation unit 73.

The pixel high-level period measuring unit 71 measures the high-level period of the first pixel after the same potential continues for a preset time or longer and the high-level period of the pixel after the first pixel.

The measurement result holding unit 72 stores the high level period of each pixel measured by the pixel high level period measuring unit 71.

The high-level period ratio calculation unit 73 has a high-level period of the first pixel measured by the pixel high-level period measurement unit 71 and a next pixel high-level period stored in the measurement result holding unit 72. Calculate the ratio of two periods.

The high-level period ratio calculation unit 73 averages the high-level period of the first pixel after the same potential continues for a preset time or longer and the high-level period of a plurality of pixels after the first pixel. You may want to compare with the value. For example, the high-level period ratio calculation unit 73 may calculate the ratio between the average value of the high-level period of the second and third pixels and the high-level period of the first pixel.

Next, the configuration of the pixel high level period measuring unit 71 will be described with reference to the block diagram of FIG.

As shown in FIG. 12, the pixel high-level period measurement unit 71 includes a reference clock generation unit 81 and a counter 82.

The counter 82 inputs the reference clock generated by the reference clock generation unit 81 at regular intervals and the image data received by the image data reception unit 61, and uses the high-level period of each pixel in the image data as a reference. Measured by the number of clocks.

A state in which the high-level period of each pixel is measured by the pixel high-level period measuring unit 71 will be described with reference to FIG.

For example, as shown in FIG. 13, the counter 82 in the pixel high-level period measuring unit 71 calculates how many clocks of the reference clock the high-level period of each pixel in the image data corresponds to, and calculates the calculation result. Output as a count value.

In the example shown in FIG. 13, it is calculated that the high level period of the first pixel is 2 clocks and the high level period of the second and third pixels is 3 clocks.

The pixel high-level period measuring unit 71 shown in FIG. 12 digitally measured the high-level period of each pixel, but as in the pixel high-level period measuring unit 71a shown in FIG. 14, each pixel was measured in an analog manner. It is also possible to configure it to measure the high level period of.

As shown in FIG. 14, the pixel high-level period measuring unit 71a includes a capacitor 83 and an operational amplifier 84.

The pixel high-level period measuring unit 71a measures the high-level period of each pixel by converting the image data received by the image data receiving unit 61 into a voltage corresponding to the high-level period of each pixel.

Specifically, in the pixel high-level period measuring unit 71a, an operational amplifier that functions as a voltage hollower at a potential charged in the capacitor 83 according to the high-level period of each pixel of the image data received by the image data receiving unit 61. It is output as an analog value by 84.

Next, a detailed configuration of the terminating resistor 70 will be described with reference to FIG.

As shown in FIG. 15, the terminating resistor 70 is composed of three resistance elements 91 to 93 and three switching elements 94 to 96 provided corresponding to the three resistance elements 91 to 93, respectively. ..

The three switching elements 94 to 96 are configured so that they can be independently turned on / off based on the output signal from the terminating resistor adjusting unit 65.

Then, each of the switching elements 94 to 96 is turned on to connect the resistance elements 91 to 93 as a terminating resistor of the differential transmission line 60.

Then, the combined resistance value of the resistance values R1, R2, and R3 of these three resistance elements 91 to 93 becomes the resistance value of the terminating resistance 70 of the differential transmission circuit 60.

The terminating resistance adjusting unit 65 adjusts the resistance value of the terminating resistor 70 by switching which of the three switching elements 94 to 96 is turned on in this way.

For example, the current resistance value of the terminating resistor 70 is set to 100Ω, and the pixel size of the first pixel is 2/3 of the pixel size of the second pixel according to the comparison result of the pixel size in the image size comparison unit 64. In this case, the switching elements 94 to 96 are switched on / off so that the resistance value of the terminating resistor 70 is close to 100 × 2/3 (Ω).

FIG. 16 shows a waveform example of the image data after the resistance value of the terminating resistor 70 has been adjusted.

Comparing the waveform example shown in FIG. 16 with the waveform example in the case where the resistance value of the terminating resistor 70 shown in FIG. 6 is a fixed value, in FIG. 16, the high level period of the first pixel (first pixel) becomes longer. It can be seen that the period is close to the high level period of the second and subsequent pixels.

This is because the resistance value of the terminating resistor 70 is adjusted to be small, so that the voltage difference (amplitude) between the two transmission lines of the differential transmission line 60 is small, and the same potential is maintained for a preset time or longer. This is because the time until the polarity of the voltage is switched is shortened even if the voltage is continuous.

In the comparison result of the pixel size comparison unit 64, the case where the pixel size of the first pixel is smaller than the pixel size of the pixel after the first pixel has been described so far, but the pixel size of the first pixel has been described. When is larger than the pixel size of the pixel after the first pixel, the termination resistance adjusting unit 65 may adjust so that the resistance value of the termination resistance 70 becomes large.

10 Image forming device 12 UI device 14 Image forming device main body 16 Image reading device 18 Recording medium supply cassette 20 Terminal device 21 Supply head 22 Recording medium supply path 24 Image forming unit 26 Photoreceptor 27 Exposure device 28 Intermediate transfer belt 29 Developing device 30 Network 31 Secondary transfer roll 32 Fixing device 34 Recording medium discharge path 36 Discharge unit 42 Document supply unit 43 Document image reader 44 Document feeder 45 Document ejection unit 50 Image processing device 51 Image data transmission unit 52 Control unit 60 Differential transmission Road 61 Image data receiving unit 62 Exposure device control unit 63 Irradiation light control unit 64 Pixel size comparison unit 65 Termination resistance adjustment unit 70 Termination resistance 71, 71a Pixel high-level period measurement unit 72 Measurement result holding unit 73 High-level period ratio calculation unit 81 Reference clock generator 82 Counter 83 Condenser 84 Arithmetic amplifier 91-93 Resistance element 94-96 Switching element

Claims (8)

A receiving means for receiving image data transmitted via a differential transmission line, and
A comparison means for comparing the pixel size of the first pixel of the image data received by the receiving means after the same potential continues for a preset time or longer and the pixel after the first pixel.
An adjusting means for adjusting the resistance value of the terminating resistance of the differential transmission line based on the comparison result in the comparing means is provided .
The comparison means
A measuring means for measuring the high-level period of the first pixel after the same potential continues for a preset time or longer and the high-level period of the pixel after the first pixel.
A calculation means for calculating the ratio of two periods measured by the measurement means is provided.
Data receiver. In the comparison result of the comparison means, the adjusting means reduces the resistance value of the terminating resistor when the pixel size of the first pixel is smaller than the pixel size of the pixel after the first pixel. The data receiving device according to claim 1 to be adjusted. The data receiving device according to claim 1 or 2, wherein the adjusting means adjusts the resistance value of the terminating resistor of the differential transmission line within a predetermined time after the power is turned on. The data receiving device according to claim 1 or 2, wherein the adjusting means adjusts the resistance value of the terminating resistance of the differential transmission line when a component that may change the state of the differential transmission line is replaced. It said measuring means, a high-level period of each pixel, the data receiving apparatus according to claim 1, wherein measuring the number of clocks of the reference clock. Said measuring means, by converting into a voltage corresponding to the high-level period of each pixel, the data receiving apparatus according to claim 1, wherein measuring the period of the high level of each pixel. A receiving means for receiving image data transmitted via a differential transmission line, and
A comparison means for comparing the pixel size of the first pixel of the image data received by the receiving means after the same potential continues for a preset time or longer and the pixel after the first pixel.
An adjusting means for adjusting the resistance value of the terminating resistance of the differential transmission line based on the comparison result in the comparing means, and
A control means for controlling the light emitted to the photoconductor based on the image data received by the receiving means is provided .
The comparison means
A measuring means for measuring the high-level period of the first pixel after the same potential continues for a preset time or longer and the high-level period of the pixel after the first pixel.
A calculation means for calculating the ratio of two periods measured by the measurement means is provided.
Exposure device. A receiving means for receiving image data transmitted via a differential transmission line, and
A comparison means for comparing the pixel size of the first pixel of the image data received by the receiving means after the same potential continues for a preset time or longer and the pixel after the first pixel.
An adjusting means for adjusting the resistance value of the terminating resistance of the differential transmission line based on the comparison result in the comparing means, and
A control means for controlling the light emitted to the photoconductor based on the image data received by the receiving means, and
It is provided with an output means for outputting an image obtained by developing a latent image formed on the photoconductor by the light controlled by the control means on a recording medium.
The comparison means
A measuring means for measuring the high-level period of the first pixel after the same potential continues for a preset time or longer and the high-level period of the pixel after the first pixel.
A calculation means for calculating the ratio of two periods measured by the measurement means is provided.
Image forming device.