JP2007225980A - Processing device having monitor connection means and method for detecting monitor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To detect in real time whether a monitor is connected on a PC main body side, in a monitor interface having no signal line for detecting monitor connection. <P>SOLUTION: Switching means SW1 and SW2 are serially connected to pull-up resistors R11 and R12 on the PC body 1 side of the DDC signal line. When the DDC is in an idle state, the switching means SW1 and SW2 are turned off, and the pull-up signals of the DDC CLK (SCL) and the DDC DATA (SDA) are made disconnected. The electric potential level of the SCL/SDA signal line is detected on the body 1 side; and when this electric potential level is changed, an interrupt signal is generated; and when the interrupt signal is generated, it is determined whether a monitor is connected or disconnected from the direction of the change in the electric potential level of the SCL/SDA signal line on the PC body 1 side. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention provides a processing apparatus and a monitor that can detect the presence or absence of a monitor connection in real time on the main body side in an interface that does not have a signal line such as a hot detect that detects monitor connection, such as an analog RGB interface. It relates to a detection method.

In recent years, there are VGA (analog RGB display), digital (DVI) display, and TV (composite, S-VIDEO, component, D terminal) as a display output monitor connected to a personal computer. One or more of these monitors are connected at the same time for display, and in a notebook personal computer or the like, an external monitor is attached or detached while the power is on.
For this reason, it is desirable to automatically detect whether the external monitor is connected on the personal computer body side.
For example, a device described in Patent Document 1 is proposed as a device that automatically detects connection of an external display device to an electronic device body and automatically switches the display from a display device built in the electronic device to an external display device. Yes. The one described in Patent Document 1 provides a signal line that is connected to each other when a connector is connected, and automatically detects the connection of an external display.

For example, a DVI monitor will be described with reference to FIG.
As shown in FIG. 5, a monitor having a DVI interface is always provided with a hot plug signal (hot detect signal) 11 that notifies the personal computer main body 10 of the connection from the monitor 20 side. Yes.
As shown in the figure, the hot plug signal is pulled down to 0 V by a resistor R13 inside the main body, and if the signal is high level, it is judged that the monitor is connected, and if the signal is low level, it is judged that the monitor is not connected. it can.
The D terminal also has a signal pin that knows whether or not there is a connection, so that the presence or absence of the cable can be notified to the main body as an interrupt signal, and can be detected in real time.
Recently, monitors that support DDC (Display DATA Channel) have become mainstream, and as shown in the figure, the monitor 20 has an EDID ROM 21 that stores information (EDID: Extended Display IDentification) relating to a display monitor. The EDID information can be taken out from the personal computer main body 10 side through the two signal lines 12 of the DDC. The two signal lines are pulled up on the personal computer main body side and the monitor side by pull-up resistors R11, R12, R21, and R22.

On the other hand, an analog RGB interface as a display interface of a personal computer does not have a dedicated signal line for hot plug as shown in FIG.
For this reason, the detection of the presence / absence of connection from the personal computer main body 10 side can be monitored by performing the following method periodically by polling.
One is to use the analog RGB 75Ω termination inside the monitor, output the pulse from the main body to any of the RGB signals, and if the reflected signal voltage level doubles, it will be unconnected, If it is 1 time, detection is performed by a method called connection.
Recently, monitors supporting the DDC (Display DATA Channel) have become mainstream, and in addition to analog RGB signals and horizontal / vertical synchronization signals (HSYNC / VSYNC), as shown in FIG. Is provided.
Therefore, in accordance with the above method, an EDID (Extended Display Identification DATA) ROM in which monitor information existing in the monitor is written via the signal line 12 of the DDC is read, and it is possible to determine whether or not the read is successful. In some cases. However, in any of the analog RGB interfaces, the presence / absence of the connection monitor is determined only when the main body is started or when the user operates an application (such as a display property) on Windows (registered trademark). .
JP-A-8-115063

There is a desire to make it possible for the main body to know in real time when the presence / absence of the connection of the display device in the analog RGB interface is removed.
For example, assume that a presentation is given in a conference room using a projector and a personal laptop computer. In that case, as a procedure, in most cases, a monitor (projector) is connected from a state in which the notebook personal computer is activated.
When the projector is a DVI interface, as described above, there is a hot detect signal and it can be displayed on the projector at the same time as the connection. However, if the projector is an analog RGB interface, there is no corresponding signal. After the cable connection, a complicated operation occurs in which the user switches the display to the projector by an application on Windows (registered trademark).

As a specification of Microsoft OS “Vista” (registered trademark) shipped after 2006, a hot plug function by a device is required in an analog RGB interface as well as DVI.
However, if a dedicated signal for hot plug is newly added to an empty terminal, the conventional monitor is completely incompatible.
The present invention has been made in view of the above circumstances, and enables the presence or absence of monitor connection to be detected in real time on the personal computer body side in a monitor interface that does not have a signal line for detecting monitor connection, such as an analog RGB interface. For the purpose.

Most of the recent analog RGB monitors have a DDATA (Display DATA Channel) signal line which is a monitor information acquisition signal line, which has a pull-up resistor to 5 V on each of the processing device main body side and the monitor side. Attached. A switching means comprising a switch such as an FET is provided between the DDC signal line and the pull-up resistor to enable ON / OFF control of the pull-up itself. When the pull-up is OFF, it is desirable to add a pull-down resistor having a larger resistance value in order to guarantee a low level.
Originally, the purpose of the pull-up resistor on the main body side is to shorten the rise time when the signal changes, so that when the signal is stopped, only the pull-up resistor on the monitor side is sufficient.
In other words, at startup, the main body side is pulled up to 5V and the monitor side is also pulled up to 5V as specified by the conventional DDC, and the main body side pull-up resistor is turned off after a certain period of time after the DDC signal access stops. And rely only on the pull-up on the monitor side.

If the monitor connector is not connected in this state, the monitor information acquisition signal line goes low. Further, when a monitor is connected when the monitor connector is not connected, the monitor information acquisition signal line is changed from low level to high level.
That is, it is possible to detect whether the monitor is not connected / connected by changing the signal line. Therefore, the change of the signal line is detected, an interrupt signal is given to the processing device body side, and it is determined that the signal line is not connected when the signal line becomes low level, and is connected when the signal line becomes high level. Can do.
The signal line becomes 0V not only when the monitor is not connected but also when there is a low output from the monitor side. Therefore, for example, when the signal line becomes 0 V, the switching means turns on the pull-up resistor on the main body side, and if the signal line becomes high level, the monitor is not connected, and the low level is low. If it remains, it can be distinguished that it is due to the low output from the monitor side.

  In the present invention, there is provided a switching means for connecting and disconnecting the pull-up signal to the monitor information acquisition signal line on the processing apparatus side, and after the processing apparatus is started up, the switching means is switched so that the pull-up signal is transmitted. When not connected and the potential level of the signal line changes, an interrupt signal is generated on the processor side, and the monitor device is connected based on the potential of the monitor information acquisition signal line when the interrupt signal is generated. Therefore, even in the case of a conventional analog RGB monitor that does not have a signal line such as hot detect for detecting the monitor connection, connection / disconnection to the processing apparatus main body is not performed. It becomes possible to detect in hardware in real time.

FIG. 1 is a diagram showing a configuration of an embodiment of the present invention, and shows a state where a personal computer main body 1 and an analog RGB display 2 are connected.
As shown in the figure, the analog RGB connector signal includes three analog RGB signals, HSYNC / VSYNC synchronization signal, and DDC (DDC CLK / DDC DATA) for reading the monitor ID. There are two signal lines 12.
Each signal line is connected to a graphic chip 1 a provided in the personal computer main body 1.
Generally, when the system of the personal computer main body 1 is activated, the main body 1 side reads the ID of the monitor 2 (EDID ROM 21) via the DDC signal in order to know the capability of the monitor 2. Once reading is completed, this signal is held at 5V by the pull-up resistor until an event such as activation or resolution change occurs again.

As shown in FIG. 1, the DDC signal line 12 is provided with pull-up resistors R11, R12, R21, and R22 on the main body side (2.2 kΩ) and the monitor side (56 kΩ), respectively.
The pull-up resistors R11 and R12 on the main body side are connected to 2.2 kΩ for the purpose of shortening the rise time of the signal. However, when this signal is stopped, only the pull-up on the monitor side is sufficient. .
Therefore, in this embodiment, switching means SW1 and SW2 such as FETs are connected in series to the pull-up resistors R11 and R12 on the main body 1 side. While the signal is stopped (idle state), the switching means SW1 and SW2 are turned off, and the pull-up signals of DDC CLK (SCL) and DDC DATA (SDA) are not connected.
As a result, the pull-up is only on the monitor 2 side. If the monitor 2 is not connected in this state, the pull-up signal disappears in the SCL / SDA signal line of the DDC on the main body 1 side.
Therefore, by connecting pull-down resistors R13 and R14 of about 200 kΩ, for example, to the DDC signal line on the main body side, the SCL / SDA signal line becomes 0V.

The main body 1 is provided with means for detecting the potential level of the SCL / SDA signal line and generating an interrupt signal when the potential level changes. Interrupt signal goes up.
As a result, the main body senses that the SCL / SDA signal line has become 0V, but at this time, it is determined whether the signal changes due to the disconnection of the monitor 2 or the LOW signal output from the monitor side. Can not.
Therefore, next, the switching means SW1 and SW2 are turned on, and the pull-up resistor is connected again.
If the signal line remains at a low level even when the switching means SW1 and SW2 are turned on, it can be determined that the monitor 2 remains connected and has become a low level by an output from the monitor 2 side. When the signal line level changes to 5V, it can be determined that the monitor is not connected.
Thereafter, the switching means SW1 and SW2 are turned OFF and the SCL / SDA signal line is set to the low level to connect to the next connection determination. After setting the level, no pull-up is performed on the main body 1 side (only pull-down on the main body side), and the SDA signal is set to the low level.

On the other hand, when the monitor cable is connected to the connector on the main body 1 side from the state where the monitor 2 is not connected, the SCL / SDA signal line is set to the high level by the pull-up resistor of the monitor.
As a result, an interrupt signal is raised on the main body 1 side as described above, and the SCL / SDA signal line becomes high level, so that it can be determined that the monitor 2 is connected. This sequence is the same as the Accessbus stop, but there is no problem with this.
In the above description, the switching means is provided in series with each pull-up resistor of the SCL and SDA signal lines. However, the switching means is provided in series with the pull-up resistor only for the SCL signal. Even if a pull-down resistor is added to only the signal, the same can be realized.

FIG. 2 is a time chart showing a change in the potential level of the DDC signal line. DDC access and monitor detection in this embodiment will be described with reference to FIG.
The DDC access bus specifications are as shown in FIG. That is, when both SDA / SCL are high level or SDA is low and SCL is high level, it is in an idle state or DDC state, SCL is high level and SDA is changed from high level to low level. If it has changed, DDC access starts, if SCL is high and SDA changes from low to high, DDC access stops (ends), and if SCL is low, SDA is D'ont Care or weight.
Further, as described above, when the main body side pull-up is not connected, both SDA / SCL changes from low to high, and further changes to low, which means that the monitor is not connected. When the SDA / SCL changes from low to high while the side pull-up is not connected, the monitor is connected.

When the personal computer main unit starts up with the analog monitor connected to the personal computer main unit, the OS of the personal computer starts up the analog monitor, enters the DDC mode, and DDC access is performed. When the SCL is at the high level, the SDC is changed from the low level to the high level, so that the DDC access is completed (section a in FIG. 2).
When the DDC access is completed, the switching means SW1 and SW2 connected in series to the pull-up resistors R11 and R12 on the main body side of the SCL / SDA signal line are turned off, the pull-up is disconnected and the hot plug mode is set ( Section b) in FIG. In this state, since the monitor cable is connected, the SCL / SDA signal line does not become low level.
Next, when performing monitor detection by an application, first, the switching means SW1 and SW2 are turned on, and the pull-up is connected. When SCL is at high level, SDA is changed from high to low level to start DDC access. And EDID data etc. are transmitted / received between a personal computer main body and a monitor via a SCL / SDA signal line. Next, when the SCL is at the high level, the SDC is changed from the low level to the high level, thereby terminating the DDC access (section c in FIG. 2).

When the DDC access is completed, the switching means SW1 and SW2 connected in series to the pull-up resistors R11 and R12 on the main body side of the SCL / SDA signal line are turned off, the pull-up is disconnected and the hot plug mode is set ( Section d) in FIG.
Here, when the monitor cable is disconnected, as shown in FIG. 2, the SCL / SDA signal line changes from the high level to the low level.
As a result, an interrupt is raised on the PC body side. As described above, the PC main unit turns on the switching means SW1 and SW2 and connects the pull-up resistor again to determine whether the signal changes due to the monitor 2 being disconnected or the LOW signal output from the monitor side. To do. When the signal lines change to high level by turning on the switching means SW1 and SW2, the main body determines that the monitor is not connected.
Next, when the monitor cable is connected again, as shown in FIG. 2, the SCL / SDA signal line changes from the low level to the high level, and an interrupt occurs on the personal computer main body side. On the main body side, it is determined that the monitor is connected when the SCL / SDA signal line changes from the low level to the high level.

  Then, for example, when starting DDC access for confirmation of an external monitor, as described above, the switching means SW1 and SW2 are turned on and the pull-up is connected. When SCL is at high level, SDA is changed from high to low level to start DDC access. And EDID data etc. are transmitted / received between a personal computer main body and a monitor via a SCL / SDA signal line. (Section e in FIG. 2).

FIG. 4 is a flowchart showing the processing of this embodiment, and the processing on the main body side will be described with reference to FIG.
FIG. 4A is a main flow. When the personal computer is started in the analog monitor connection state, the gate signal of the switching means connected in series with the pull-up resistor is turned on and the pull-up resistor is connected (step S1). ~ S2). Then, the DDC access is started and the EDID data of the monitor is read (step S3).
When the activation of the OS is completed, the gate of the switching means connected in series with the pull-up resistor is turned off, the pull-up resistor is not connected, and acceptance of the monitor insertion / extraction interrupt is started (steps S4 and S5).
Thereafter, normal operation / work is performed until an interruption occurs (steps S6 and S7).

On the other hand, when the potential level of the SCL / SDA signal line changes as described above and the interrupt process is performed, the interrupt process shown in FIG. 4B is performed.
When there is an interrupt, it is checked whether a monitor is currently connected to the main body (step T1). If the monitor is not connected, it is checked whether the potential level of the SCL / SDA signal line has increased (step T2). If the potential level of the SCL / SDA signal line is not increased, the process returns. If the potential level of the SCL / SDA signal line is increased, it is determined that the monitor is connected (steps T2 and T3).
If the monitor is currently connected, the process goes from step T1 to T4 to check whether the potential level of the SCL / SDA signal line has dropped. If the potential level of the SCL / SDA signal line is not lowered, the process returns. If the potential level of the SCL / SDA signal line is lowered, the gate of the switching means is turned on and the pull-up resistor is connected. (Steps T4 and T5).
Then, the potential level of the SCL / SDA signal line at that time is examined, and if it is high level, it is determined that the analog display is not connected (steps T6 and T7). Then, the gate of the switching means is turned off to prepare for the next detection (step T8). For example, when the personal computer body is a notebook computer, the image displayed on the analog display is displayed on the liquid crystal screen of the notebook computer (step T9).
On the other hand, if it is determined in step T6 that the potential level of the SCL / SDA signal line is low, it is determined that the analog display is connected (step T10), and the process returns.

It is a figure which shows the structure of the Example of this invention. It is a time chart which shows the change of the electric potential level of a DDC signal line. It is a figure which shows the access bus specification of DDC. It is a flowchart which shows the process by the side of the main body in the Example of this invention. It is a figure which shows the connection of a personal computer and a DVI monitor. It is a figure (conventional example) which shows the connection of a personal computer and an analog RGB monitor.

Explanation of symbols

1 PC body 2 Analog RGB monitor R11, R12 Pull-up resistor (on the body side)
R21, R22 Pull-up resistors (monitor side)
R13, R14 pull-down resistor SW1, SW2 switching means (switching means)

Claims (3)

A processing device having an interface including an analog video signal, a horizontal / vertical synchronization signal, and a monitor information acquisition signal line pulled up on the monitor side, to which the monitor device is connected,
The monitor information acquisition signal line on the processor side is provided with a pull-up means and a switching means for connecting and disconnecting the pull-up signal,
In the processing device, the potential level of the monitor information acquisition signal line is detected, an interrupt signal is generated when the potential level changes, and after the start-up processing of the processing device, the switching means is switched, A monitor detection means is provided for detecting whether or not the monitor device is connected based on the potential of the monitor information acquisition signal line when the pull-up signal is not connected and the interrupt signal is generated. A processing device. When the interrupt signal is generated when the monitor is connected, the monitor detection means switches the switching means to connect a pull-up signal, and at that time, based on the potential of the monitor information acquisition signal line, The processing apparatus according to claim 1, wherein connection or non-connection of a monitor is detected. It has an interface including an analog video signal, horizontal / vertical synchronization signal, and a monitor information acquisition signal line pulled up on the monitor side, and the monitor information acquisition signal line is pulled up to be switched between connected and unconnected, A monitor detection method in a processing device to which a monitor device is connected via the interface,
After the processing device startup processing, the step of disconnecting the pull-up,
Detecting a potential level of the monitor information acquisition signal line and generating an interrupt signal when the potential level changes;
A monitor detection method comprising a step of detecting whether or not a monitor device is connected based on a potential of a monitor information acquisition signal line when the interrupt signal is generated.

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