JP6172749B2 - Video signal processing device - Google Patents

Description

  The present invention relates to a video signal processing apparatus.

  A video signal processing apparatus that performs video signal processing on a video signal typically includes an input unit that receives the video signal, an integrated circuit that performs video signal processing on the video signal input to the input unit, and an integrated circuit And an output unit for outputting a video signal on which video signal processing has been performed.

  Since there are various types of transmission standards for transmitting video signals, the video signal processing apparatus may be provided with a plurality of input units corresponding to each of a plurality of transmission standards. In this case, the video signal processing apparatus includes a selection circuit that selects a video signal output from the output unit from the video signals input to the input units (see Patent Document 1).

  Some video signal processing apparatuses include a plurality of output units. For example, some video signal processing devices include an output unit that outputs a video signal to an internal display device and an output unit that outputs the video signal to an external device.

JP 2010-008937 A

  When the video signal processing apparatus has a plurality of input units and a plurality of output units, the video signal output from the output unit can be selected from the video signals input to the input units for each output unit. It is desirable to do so. However, in this case, the video signal processing apparatus needs to be provided with a selection circuit that selects a video signal output from the output unit from the video signals input to each input unit for each output unit. There was a problem of increasing. Hereinafter, this problem will be described with reference to FIGS.

  FIG. 5 is a block diagram illustrating an example of a configuration of a video signal processing apparatus having a plurality of input units and a plurality of output units.

  The video signal processing apparatus 800 shown in FIG. 5 includes a first input unit 801, a second input unit 802, a first output unit 803, a second output unit 804, a first selection circuit 805, and an integrated circuit 806. And having. Further, the integrated circuit 806 includes a second selection circuit 807.

  Video signals are input to the first input unit 801 and the second input unit 802, and the first input unit 801 and the second input unit 802 output the input video signals to the first selection circuit 805 and the integrated circuit 806. To do.

  The first selection circuit 805 receives video signals output from the first input unit 801 and the second input unit 802, selects one of the video signals, and outputs the selected video signal to the first output unit 803.

  The second selection circuit 807 receives the video signal output from the first input unit 801 via the input terminal 808 of the integrated circuit 806, and receives the video signal output from the second input unit 802 as the input terminal 809 of the integrated circuit 806. Accept through. The second selection circuit 807 selects one of the received video signals and outputs it to the second output unit 804 via the output terminal 810 of the integrated circuit 806.

  As described above, in the video signal processing apparatus 800, since a selection circuit is provided for each output unit, a space for providing the first selection circuit 805 in addition to the integrated circuit 806, and the first input unit 801 and the second input unit 802 respectively. A space for providing a signal line for inputting a video signal to the 1 selection circuit 805 and the integrated circuit 806 is required. Therefore, there is a problem that the circuit scale increases. In particular, when the video signal input to the first selection circuit 805 is a parallel signal, the number of signal lines is required to be the same as the number of signals transmitted in parallel, and the circuit scale can be increased by providing a selection circuit for each output unit. Increase greatly.

  In FIG. 5, one of the two selection circuits is provided outside the integrated circuit. However, both of the two selection circuits may be provided in one integrated circuit.

  FIG. 6 is a block diagram showing an example of a configuration of a video signal processing apparatus in which both of two selection circuits are provided in one integrated circuit.

  The video signal processing apparatus 900 shown in FIG. 6 includes a first input unit 901, a second input unit 902, a first output unit 903, a second output unit 904, and an integrated circuit 905. Further, the integrated circuit 905 includes a first selection circuit 906 and a second selection circuit 907.

  Video signals are input to the first input unit 901 and the second input unit 902, and the first input unit 901 and the second input unit 902 output the input video signals to the integrated circuit 905.

  Each of the first selection circuit 906 and the second selection circuit 907 receives the video signal output from the first input unit 901 via the input terminal 908 of the integrated circuit 905, and receives the video signal output from the second input unit 902. It accepts via the input terminal 909 of 905. The first selection circuit 906 selects one of the received video signals and outputs it to the first output unit 903 via the output terminal 911 of the integrated circuit 905. The second selection circuit 907 selects one of the received video signals and outputs the selected video signal to the second output unit 904 via the output terminal 910 of the integrated circuit 905.

  As described above, in the video signal processing apparatus 900, compared to the video signal processing apparatus 800, two selection circuits are provided in one integrated circuit 905. Therefore, when the first selection circuit 906 can be provided in the integrated circuit 905 without changing the scale of the integrated circuit 905, a space for providing the first selection circuit 906 can be omitted. However, in this case, an output terminal 911 for outputting the video signal output from the first selection circuit 906 to the outside of the integrated circuit 905 is required, and the number of input / output terminals provided in the integrated circuit 905 increases, and the scale of the integrated circuit 905 increases. Resulting in. In addition, signal lines around the integrated circuit 806 become complicated, and the circuit scale around the integrated circuit 806 increases. For this reason, the increase in circuit scale cannot be sufficiently suppressed only by providing both of the two selection circuits in the integrated circuit 905.

  An object of the present invention is to provide a video signal processing device capable of suppressing an increase in circuit scale even when a plurality of output units for outputting video signals are provided.

The video signal processing apparatus according to the present invention is:
A first input unit and a second input unit to which a video signal is input;
From a first terminal to which a video signal from the first input unit is input, a second terminal to which a video signal from the second input unit is input, and a video signal from the first terminal or the second terminal A selection unit for selecting the video signal, a third terminal for outputting the video signal selected by the selection unit, and a path for transmitting the video signal from the second terminal to the first terminal. The first terminal functions as an input terminal for inputting a video signal from the first input unit, and the first terminal functions as an output terminal for outputting a video signal from the second input unit. An integrated circuit having a switching unit for switching between states,
A first output unit that outputs a video signal from the first input unit or a video signal from the first terminal of the integrated circuit.

  According to the present invention, it is possible to suppress an increase in circuit scale even when there are a plurality of output units that output video signals.

It is a block diagram which shows the structure of the display apparatus concerning the 1st Embodiment of this invention. 4 is a flowchart for explaining an output switching operation of the display device according to the embodiment. It is a block diagram which shows the structure of the display apparatus concerning the 2nd Embodiment of this invention. 4 is a flowchart for explaining an output switching operation of the display device according to the embodiment. It is a block diagram which shows the structural example of the video signal processing apparatus using the technique relevant to this invention. It is a block diagram which shows the other structural example of the video signal processing apparatus using the technique relevant to this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In addition, in this specification and drawing, the description which overlaps may be abbreviate | omitted by attaching | subjecting the same code | symbol about the component which has the same function.

(First embodiment)
FIG. 1 is a block diagram showing a configuration of a display device 100 according to the first embodiment of the present invention.

  The display device 100 is a video signal processing device that processes an input video signal, and includes a first input terminal 101, a video signal receiving unit 102, a second input terminal 103, an AD (Analog Digital) converter unit 104, and the like. Have The display device 100 further includes a video signal transmission unit 105, an output terminal 106, a scaler unit 107, a display unit 108, an integrated circuit unit 109, and a control unit 120.

  The first input terminal 101 receives a serial digital video signal in accordance with a standard such as HDMI (registered trademark) (High-Definition Multimedia Interface) / Display Port / DVI (Digital Visual Interface) from an external device (not shown). Received and output to the video signal receiving unit 102. Hereinafter, the video signal input to the display device 100 via the first input terminal 101 may be referred to as a first video signal.

  The video signal receiving unit 102 receives the video signal output from the first input terminal 101, performs reception processing on the video signal, and outputs the video signal after the reception processing. Note that the video signal receiving unit 102 may be referred to as a first input unit. For example, when the video signal is a serial digital video signal, the video signal receiving unit 102 performs a process of converting the serial video signal into a parallel video signal as a reception process.

  The video signal receiving unit 102 is connected to the video signal transmitting unit 105 and the integrated circuit unit 109 via the node N, respectively. The path for transmitting the video signal from the video signal receiving unit 102 to the video signal transmitting unit 105 is shared with the node N from the path for transmitting the video signal from the video signal receiving unit 102 to the integrated circuit unit 109. Branch from node N.

  For example, when the digital video signal is composed of R, G, and B video signals and converted into 8-bit parallel digital video signals, the video signal receiving unit 102 includes the video signal transmitting unit 105 and the integrated circuit unit 109. 3 × 8 = 24 signal lines are used for connection. Hereinafter, for the sake of simplicity, only one signal line to be connected is shown and described. The terminals to which the signal lines are connected may be a terminal group that is a set of terminals to which a plurality of signal lines are respectively connected.

  Further, the video signal receiving unit 102 outputs the output of the video signal receiving unit 102 according to the control signal from the control unit 120, the output state of outputting the signal according to the input video signal, and does not output the video signal. A function to switch between high impedance states is provided. Here, the high impedance state is a state where the impedance of the video signal receiving unit 102 viewed from the node N is high, for example. By setting the output to the high impedance state, the video signal receiving unit 102 can stop the input of the video signal to the first terminal 110.

  The second input terminal 103 receives an analog video signal from an external device (not shown) and outputs it. Hereinafter, a video signal input to the display device 100 via the second input terminal 103 may be referred to as a second video signal.

  The AD converter unit 104 receives the analog video signal from the second input terminal 103, converts the analog video signal into a parallel digital video signal, and outputs the converted digital video signal. For example, when the analog video signal is composed of R, G, and B video signals and converted into 8-bit parallel digital video signals, the video signal receiving unit 102 includes the integrated circuit unit 109 and 3 × 8 = 24 lines. The signal line is used for connection. The AD converter unit 104 may be referred to as a second input unit.

  The video signal transmitting unit 105 receives the video signal from the video signal receiving unit 102 or the video signal from the integrated circuit unit 109 and converts the received video signal in accordance with the standard supported by the output terminal 106. The first output unit outputs the converted video signal. Specifically, the video signal transmission unit 105 converts the received parallel digital video signal into a serial digital video signal in accordance with a standard such as HDMI / Display Port / DVI.

  The scaler unit 107 receives a video signal from the integrated circuit unit 109 and performs a scaling process for enlarging or reducing the image indicated by the received video signal in accordance with, for example, the resolution of the display unit 108. The scaler unit 107 is also called a second output unit, and outputs a video signal after scaling processing.

  The display unit 108 includes a display element, a driving unit that drives the display element, and the like, receives a video signal from the scaler unit 107, and displays an image corresponding to the received video signal. Specifically, the display unit 108 is a liquid crystal display using a liquid crystal panel as a display element, or an organic EL display using an organic EL (ElectroLuminescence) panel as a display element. The display unit 108 may be a DLP (Digital Light Processing) projector using a DMD (Digital Micromirror Device) panel as a display element.

  The integrated circuit unit 109 is an FPGA (Field Programmable Gate Array) or an ASIC (Application Specific Integrated Circuit). The integrated circuit unit 109 includes a first terminal 110, a second terminal 111, a selection circuit 112, a third terminal 113, and a three-state buffer 114.

  The first terminal 110 is a bidirectional terminal that functions as an input terminal to which a video signal from the video signal receiving unit 102 is input or an output terminal that outputs a video signal from the second terminal 111. The first terminal 110 is connected to a node N on a path for transmitting a video signal from the video signal receiving unit 102 to the video signal transmitting unit 105, and the first terminal 110 and the node N are connected by a bidirectional line. ing. For this reason, the first terminal 110 can input the video signal from the second terminal 111 to the video signal transmission unit 105.

  The second terminal 111 is an input terminal to which a video signal from the AD converter unit 104 is input. The video signal from the second terminal 111 is input to the three-state buffer 114 and the selection circuit 112, respectively.

  The selection circuit 112 is a selection unit that selects a video signal from the first terminal 110 or a video signal from the second terminal 111. Specifically, the selection circuit 112 receives a control signal from the control unit 120 and selects a video signal to be displayed on the display unit 108 according to the control signal. The selection circuit 112 makes the input terminal to which the selected video signal is input out of the first terminal 110 and the second terminal 111 conductive with the third terminal 113.

  The third terminal 113 is an output terminal that outputs the video signal from the video signal receiving unit 102 or the video signal from the AD converter unit 104 to the scaler unit 107. Since the third terminal 113 is electrically connected to the terminal selected by the selection circuit 112 of the first terminal 110 or the second terminal 111, the video signal from the first terminal 110 or the video signal from the second terminal 111 is scaled. This is output to the unit 107.

  The three-state buffer 114 is disposed between the first terminal 110 and the second terminal 111, and by setting its own output to a high impedance state or a low impedance state, a path between the first terminal 110 and the second terminal 111. Is turned on or off. Specifically, the control input of the three-state buffer 114 is connected to the control unit 120. Then, the three-state buffer 114 conducts or cuts off a path for transmitting the video signal from the second terminal 111 to the first terminal 110 in accordance with a control signal from the control unit 120, and sets the output to a high impedance state. Then, the above route is blocked. Thus, when the three-state buffer 114 conducts a path for transmitting the video signal from the second terminal 111 to the first terminal 110, the first terminal 110 functions as an output terminal. In addition, when the three-state buffer 114 cuts off the path for transmitting the video signal from the second terminal 111 to the first terminal 110, the first terminal 110 can function as an input terminal. Accordingly, the three-state buffer 114 conducts or cuts off a path for transmitting the video signal from the second terminal 111 to the first terminal 110, thereby causing the first terminal 110 to function as an input terminal and the first terminal 110. Is a switching unit that switches between a state that functions as a force terminal.

  Although omitted for simplicity, the integrated circuit unit 109 includes a configuration for performing various types of video signal processing on the first video signal or the second video signal output from the selection circuit 112. An example of video signal processing performed by the integrated circuit unit 109 includes amplification of a video signal.

  The control unit 120 controls the display device 100. In the present embodiment, when an operation unit (not shown) detects an operation signal corresponding to a user operation, the control unit 120 controls the video signal receiving unit 102, the integrated circuit unit 109, and the like based on the detected operation signal. Is output.

  Specifically, when the operation unit (not shown) detects an operation signal for selecting a video signal to be output to the video signal transmission unit 105 and the scaler unit 107, the control unit 120 determines whether the operation signal is detected. A selection signal indicating a video signal to be output to the video signal transmission unit 105 and the scaler unit 107 is generated. In response to the selection signal, the control unit 120 outputs a control signal to the video signal receiving unit 102, the three-state buffer 114 of the integrated circuit unit 109, and the selection circuit 112.

  When outputting the video signal from the video signal receiving unit 102 to the video signal transmitting unit 105, the control unit 120 sets the output of the three-state buffer 114 to a high impedance state, so that the first terminal 110, the second terminal 111, And the output of the video signal receiving unit 102 is turned on.

  In addition, when the video signal transmission unit 105 outputs the video signal from the integrated circuit unit 109, the control unit 120 causes the three-state buffer 114 to conduct the path between the first terminal 110 and the second terminal 111, and the video signal is transmitted. The output of the signal receiving unit 102 is turned off and stopped.

  In this way, by turning on or off the output of the video signal receiving unit 102 in accordance with the state of the three-state buffer 114, the output of the three-state buffer 114 in the bidirectional line unit connected to the first terminal 110. And the output of the video signal receiving unit 102 can be prevented from affecting each other.

  When the scaler unit 107 outputs the video signal from the video signal receiving unit 102, the control unit 120 causes the selection circuit 112 to connect the third terminal 113 to the first terminal 110. When the video signal from the AD converter unit 104 is output to the scaler unit 107, the control unit 120 causes the selection circuit 112 to connect the third terminal 113 to the second terminal 111.

  FIG. 2 is a flowchart for explaining the output switching operation of the display device 100 according to the first embodiment of the present invention.

  The control unit 120 determines whether an output switching operation for switching the video signal output to the display unit 108 and the output terminal 106 has been detected (step S100).

  When the output switching operation is detected, the control unit 120 determines whether the video signal output to the display unit 108 selected according to the output switching operation is the first video signal or the second video signal. (Step S105).

  When the video signal output to the display unit 108 is the first video signal, the control unit 120 causes the selection circuit 112 to connect the third terminal 113 to the first terminal 110 (step S110). Then, the control unit 120 sets the three-state buffer 114 to a high impedance state, blocks the path between the first terminal 110 and the second terminal 111, and causes the video signal receiving unit 102 to turn on the output (step S115). Accordingly, the first terminal 110 functions as an input terminal to which the video signal from the video signal receiving unit 102 is input.

  On the other hand, when the video signal output to the display unit 108 is the second video signal, the control unit 120 causes the selection circuit 112 to connect the third terminal 113 to the second terminal 111 (step S120).

  Subsequently, the control unit 120 determines whether the video signal output to the output terminal 106 selected according to the output switching operation is the first video signal or the second video signal (step S125).

  When the video signal output to the output terminal 106 is the first video signal, the control unit 120 executes the process of step S115.

  On the other hand, when the video signal output to the output terminal 106 is the second video signal, the control unit 120 sets the three-state buffer 114 to a low impedance state, and sets a path between the first terminal 110 and the second terminal 111. Conduction is performed, and the video signal receiving unit 102 is turned off (step S130). Thus, the first terminal 110 functions as an output terminal that outputs the video signal from the second terminal 111.

  As described above, according to the present embodiment, the display device 100 includes the video signal receiving unit 102 and the AD converter unit 104 to which the video signal is input, the integrated circuit unit 109, and the video from the video signal receiving unit 102. A video signal transmission unit 105 that outputs a signal or a video signal from the integrated circuit unit 109. The integrated circuit unit 109 includes a first terminal 110 to which the video signal from the video signal receiving unit 102 is input, and a second terminal 111 to which the video signal from the AD converter unit 104 is input. The integrated circuit unit 109 also includes a selection circuit 112 that selects a video signal from the first terminal 110 or a video signal from the second terminal 111, a third terminal 113 that outputs the video signal selected by the selection circuit 112, A three-state buffer 114 for conducting or blocking a path for transmitting a video signal from the second terminal 111 to the first terminal 110; In the three-state buffer 114, the first terminal 110 functions as an input terminal to which a video signal is input from the video signal receiving unit 102, and the first terminal 110 The state of functioning as an output terminal for outputting a video signal from the converter unit 104 is switched.

  Thus, the input terminal to which the video signal from the video signal receiving unit 102 is input and the output terminal from which the video signal from the AD converter unit 104 is output from the integrated circuit unit 109 to the integrated circuit unit 109 are 1 It is composed of two first terminals 110. Therefore, all the configurations for selecting a video signal to be output to the video signal transmission unit 105 can be provided in the integrated circuit unit 109 without increasing the number of input / output terminals of the integrated circuit unit 109. Therefore, even when there are a plurality of output units, it is possible to suppress an increase in circuit scale.

  When the video signal input to the integrated circuit unit 109 is a parallel signal, the number of wiring lines for transmitting the video signal and the number of input / output terminals of the integrated circuit unit 109 are the same as the number of signals transmitted in parallel. . For this reason, when the video signal is a parallel signal, the effect of suppressing an increase in circuit scale is great.

(Second Embodiment)
FIG. 3 is a block diagram showing the configuration of the display device 200 according to the second embodiment of the present invention.

  The display device 200 includes a first input terminal 201, a video signal receiving unit 202, a second input terminal 203, an AD converter unit 204, a video signal transmitting unit 205, an output terminal 206, a scaler unit 207, and a display. The video signal processing apparatus includes a unit 208, an integrated circuit unit 209, and a control unit 220.

  Each part of the display device 200 corresponds to each part of the display device 100. Specifically, the first input terminal 201, the video signal receiving unit 202, the second input terminal 203, and the AD converter unit 204 are the first input terminal 101, the video signal receiving unit 102, the second input terminal 103, and the AD. Each of the converter units 104 has the same function. In addition, the video signal transmission unit 205, the output terminal 206, the scaler unit 207, the display unit 208, the integrated circuit unit 209, and the control unit 220 are the video signal transmission unit 105, the output terminal 106, the scaler unit 107, and the display unit 108, respectively. The integrated circuit unit 109 and the control unit 120 have the same functions.

  Hereinafter, description of functions common to the display device 100 will be omitted, and differences from the display device 100 will be mainly described.

  In addition to the configuration of the display device 100, the display device 200 has a configuration for transmitting the first video signal in two layers. Specifically, in addition to the configuration of the integrated circuit unit 109, the integrated circuit unit 209 outputs the video signal to the fourth terminal 215 to which the video signal from the video signal receiving unit 202 is input and the scaler unit 207. 5 terminals 216.

  As a result, there are two paths through which the first video signal is input from the video signal receiving unit 202 to the scaler unit 207. The first layer path is a path that is input to the scaler unit 207 via the fourth terminal 215 and the fifth terminal 216, and the second layer path is the scaler via the first terminal 210 and the third terminal 213. This is a route input to the unit 207.

  Then, the video signal receiving unit 202 can output the first video signal to the scaler unit 207 using at least one of the first layer path and the second layer path in accordance with an instruction from the control unit 220. The control unit 220 determines whether or not the video signal receiving unit 202 inputs the video signal to the first terminal 210 and the fourth terminal 215 based on the resolution of the video signal from the video signal receiving unit 202. Specifically, when the video signal from the video signal receiving unit 202 has a predetermined resolution or higher, the control unit 220 causes the video signal receiving unit 202 to divide the video signal, and the divided video signal is sent to the first terminal. 210 and the fourth terminal 215 are input. In addition, when the video signal from the video signal receiving unit 202 is less than the predetermined resolution, the control unit 220 causes the video signal receiving unit 202 to input the video signal to the fourth terminal 215.

  Further, when the first video signal divided into two layers is output from the third terminal 213 and the fifth terminal 216, the scaler unit 207 performs a scaling process on the first video signal of the two layers. I do. When the two-layer first video signal is output from the scaler unit 207, the display unit 208 can display an image corresponding to the two-layer first video signal. In this case, since the data amount of the video signal processed by each path is reduced, the clock frequency can be reduced.

  FIG. 4 is a flowchart for explaining an output switching operation of the display device 200 according to the second embodiment of the present invention.

  The control unit 220 determines whether an output switching operation for switching the video signal output to the display unit 208 and the output terminal 206 has been detected (step S200).

  When the output switching operation is detected, the control unit 220 determines whether the video signal output to the display unit 208 selected according to the output switching operation is the first video signal or the second video signal. (Step S205).

  When the video signal output to the display unit 208 is the first video signal, the control unit 220 causes the third terminal 212 to conduct the third terminal 213 with the first terminal 210 (step S210).

  Subsequently, the control unit 220 determines whether or not the resolution of the first video signal is greater than or equal to a threshold value (step S215).

  If the resolution of the first video signal is equal to or higher than the threshold, the control unit 220 causes the video signal receiving unit 202 to divide the first video signal (step 220). Then, the control unit 220 sets the three-state buffer 214 to a high impedance state, interrupts the path between the first terminal 210 and the second terminal 211, and turns on the output of the video signal receiving unit 202 (step S225).

  On the other hand, when the video signal output to the display unit 208 is the second video signal, the control unit 220 causes the third terminal 212 to be electrically connected to the second terminal 211 (step S230).

  Then, after executing the process of step S230 and when the resolution of the first video signal is less than the threshold value in step S215, the control unit 220 continues to output the video signal output from the output terminal 206 as the first video signal. Whether it is the second video signal or not is determined (step S235).

  When the video signal output from the output terminal 206 is the first video signal, the control unit 220 executes the process of step S225. On the other hand, when the video signal output from the output terminal 206 is the second video signal, the control unit 220 sets the three-state buffer 214 in a low impedance state and conducts the path between the first terminal 210 and the second terminal 211. The output of the video signal receiving unit 202 is turned off (step S240).

  As described above, also in this embodiment, the integrated circuit unit 209 receives the video signal from the video signal receiving unit 202 and the video signal from the AD converter unit 204 as an integrated circuit unit. The output terminals output from 209 are integrated into one first terminal 210. Therefore, a configuration for selecting a video signal to be output to the video signal transmission unit 205 can be provided in the integrated circuit unit 209 without increasing the number of input / output terminals of the integrated circuit unit 209. Therefore, even when there are a plurality of output units, it is possible to suppress an increase in circuit scale.

  In addition, when the video signal input to the integrated circuit unit 209 is a parallel signal, the number of wiring lines for transmitting the video signal and the number of input / output terminals of the integrated circuit unit 209 are the same as the number of signals transmitted in parallel. . For this reason, when the video signal is a parallel signal, the effect of suppressing an increase in circuit scale is great.

  Further, according to the present embodiment, the integrated circuit unit 209 receives the first video signal input from the video signal receiving unit 202 serving as the first input unit to the fourth terminal 215 and the fourth terminal 215. A fifth terminal 216 is further provided for outputting the video signal to the scaler unit 207 as the first output unit. As a result, the first video signal can be divided and output to the scaler unit 207 through two paths. When the first video signal is output to the scaler unit 207 using two paths, the data amount of the video signal processed through each path can be reduced, so even if the resolution of the first video signal is large The clock frequency can be reduced.

  Further, according to the present embodiment, since there are two paths for the video signal receiving unit 202 to output the first video signal to the scaler unit 207, the first video signal is output using a two-layer path. Except for this, it is possible to output an arbitrary video signal to the video signal transmission unit 205 regardless of whether the video signal output to the display unit 208 is the first video signal or the second video signal.

  While the present invention has been described with reference to the embodiments, the present invention is not limited to the above embodiments. Various changes that can be understood by those skilled in the art can be made to the configuration and details of the present invention within the scope of the present invention.

  For example, in the above embodiment, an operation signal is generated according to the user's output switching operation, and the states of the selection circuits 112 and 214 and the three-state buffers 114 and 213 are switched based on the operation signal. The invention is not limited to such examples. For example, when it is detected that an external device is connected to the first input terminals 101 and 201 or the second input terminals 103 and 203, an operation signal may be generated based on this detection information.

  Moreover, in the said embodiment, a display apparatus is mentioned as an example of a video signal processing apparatus, a 1st output part is a scaler part which outputs a video signal to a display part, and a 2nd output part is a video to the output terminal to an external device. Although the case where the video signal transmitting unit outputs a signal has been described, the present invention is not limited to such an example. For example, the video signal processing apparatus may be a scaler unit in which both the first output unit and the second output unit output a video signal to the display unit. The video signal processing device may be a video signal transmission unit in which both the first output unit and the second output unit output a video signal to an output terminal to an external device.

  In the first embodiment, the scaler unit 107 is a circuit different from the integrated circuit unit 109, but the present invention is not limited to this example. For example, the scaler unit 107 may be provided in the integrated circuit unit 109. In this case, the drive unit included in the display unit 108 can be used as the second output unit. The same applies to the scaler unit 207 in the second embodiment.

  In the above embodiment, the video signal transmission unit 105 and the video signal transmission unit 205, which are the first output units, convert the received parallel digital video signal into a serial digital signal according to a standard such as HDMI / Display Port / DVI. Although converted into a video signal and output, the present invention is not limited to such an example. For example, the video signal transmission unit 105 and the video signal transmission unit 205 may convert the received parallel digital video signal into an analog video signal and output the analog video signal.

  In the above embodiment, the first input unit receives a digital video signal and the second input unit receives an analog video signal. However, the present invention is not limited to such an example. For example, both the first input unit and the second input unit may receive a digital video signal, or both the first input unit and the second input unit may receive an analog video signal. Further, the AD converter unit 104 and the AD converter unit 204 may be provided in the integrated circuit unit 109 or the integrated circuit unit 209. In this case, the second input terminal 103 and the second input terminal 203 can be used as the second input unit.

  In the above embodiment, a three-state buffer that shuts off the signal by setting the output to a high impedance state is used as the switching unit that cuts off the path for transmitting the video signal from the second terminal 111 to the first terminal 110. The invention is not limited to such examples. For example, a switch that physically cuts off (disconnects) the path can be used.

  Various circuits may be provided between the units of the display device 100 and the display device 200 shown in the above embodiments.

100, 200 Display devices 101, 201 First input terminals 102, 202 Video signal receiving unit (first input unit)
103, 203 Second input terminal 104, 204 AD converter section (second input section)
105, 205 Video signal transmission unit (first output unit)
106,206 Output terminal 107,207 Scaler part (second output part)
108, 208 Display unit 109, 209 Integrated circuit unit 110, 210 First terminal 111, 211 Second terminal 112, 212 Selection circuit 113, 213 Third terminal 114, 214 Three-state buffer 215 Fourth terminal 216 Fifth terminal 120, 220 Control unit

Claims (8)

A first input unit and a second input unit to which a video signal is input;
From a first terminal to which a video signal from the first input unit is input, a second terminal to which a video signal from the second input unit is input, and a video signal from the first terminal or the second terminal A selection unit for selecting the video signal, a third terminal for outputting the video signal selected by the selection unit, and a path for transmitting the video signal from the second terminal to the first terminal. The first terminal functions as an input terminal for inputting a video signal from the first input unit, and the first terminal functions as an output terminal for outputting a video signal from the second input unit. An integrated circuit having a switching unit for switching between states,
And a first output unit that outputs a video signal from the first input unit or a video signal from the first terminal of the integrated circuit.   The video signal processing apparatus according to claim 1, wherein the switching unit is provided between the first terminal and the second terminal and blocks the path by setting its output to a high impedance state.   The video signal processing apparatus according to claim 1, further comprising a second output unit that outputs a video signal from the third terminal.   4. The video according to claim 1, further comprising a control unit that causes the switching unit to conduct or block the path based on a selection signal indicating a video signal to be output to the first output unit. 5. Signal processing device.   The video signal processing apparatus according to claim 4, wherein the control unit stops input of a video signal to the first terminal of the first input unit when the switching unit is caused to conduct the path. The integrated circuit comprises:
A fourth terminal to which a video signal from the first input unit is input;
A fifth terminal that outputs a video signal from the fourth terminal;
The selection signal further indicates a video signal to be output from the third terminal,
The control unit determines whether the first input unit inputs a video signal to the first terminal and the fourth terminal based on the selection signal and the resolution of the video signal, and the switching The video signal processing apparatus according to claim 4, wherein the path is made to conduct or block the path.   When the selection signal indicates that the video signal input to the first input unit is output from the third terminal, the resolution of the video signal from the first input unit is equal to or higher than a predetermined resolution. The first input unit divides the video signal, the divided video signal is input to the first terminal and the fourth terminal, respectively, and the resolution of the video signal from the first input unit is The video signal processing apparatus according to claim 6, wherein when the video signal is less than a predetermined resolution, the video signal from the first input unit is input to the fourth terminal.   The video signal processing apparatus according to claim 1, wherein the video signal input to the integrated circuit is a parallel signal.

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