KR20010008481A - Method for managing connection of digital interface - Google Patents

Abstract

PURPOSE: A method for managing connection of digital interfaces is provided to control access from a third apparatus to a bit stream while being transferred by preparing a control field established in a specific memory area. CONSTITUTION: A control field is established in oPCR as a specific memory area of a source apparatus(310). While connecting the source apparatus with a synchronizing apparatus(320), a private bit stream is transferred after marking an indication in the control field. In the case of receiving an access demand from a third apparatus(330) to the bit stream in transfer, the access from the third apparatus is controlled by referring the indication marked in a specific memory area of oPCR in the source apparatus.

Description

Method for managing connection of digital interface

The present invention relates to a digital interface connection management method, and more particularly, to a connection management method between digital devices connected through a digital interface such as IEEE1394.

Digital devices such as digital TVs, digital VCRs, and digital set-top boxes are emerging, and IEEE 1394, a network that allows these digital devices to interface with each other, is being introduced (see IEEE1394-1995 High Performance Serial Bus, IEC 61883, etc.). .

In systems where multiple digital devices are interconnected through digital interfaces such as IEEE 1394, the IEC61883 standard specifies connection management between these digital devices. The IEC61883 standard defines an input plug and an output plug as an inlet and an outlet for a bitstream for each digital device, and also includes an output master plug register (oMPR) contained within each digital device. ) manages input and output plugs to manage connection between digital devices by managing output plug control registers (oPCRs), input master plug registers (iMPRs), and input plug control registers (iPCRs).

There are two types of connection between digital devices: point-to-point connection and broadcast connection. A point-to-point connection is a connection consisting of an output plug, an input plug, and these different channels so that any digital device can establish / overlay the connection and establish the connection. One device is responsible for all the management of the connection. A broadcast connection is divided into a broadcast-in connection and a broadcast-out connection. The broadcast connection is a connection between an input plug and a channel, and the broadcast connection is a connection between an output plug and a channel. Connection. The broadcast connection can only be established by the device that actually inputs and outputs the bitstream by this connection, and the release of the connection can be established by any device on the network. All management, including the establishment or release of point-to-point and brocast connections, uses the iMPR, oMPR, iPCR, and oPCR registers.

1 illustrates a digital interface connection management method according to the prior art.

Device 1 110 is called the source device (e.g. DVCR), Device 2 120 is called the sink device (e.g. DTV), and Device 3 130 is called another sink device (e.g. DTV).

When device 1 110 and device 2 120 are connected through a point-to-point connection, the content of oPCR of device 1 110 is oPCR.P-2-P_Connection_Counter = 1, oPCR.Channel_Number = 33, The contents of the iPCR of 2 120 are iPCR.P-2-P_Connection_Counter = 1 and iPCR.Channel_Number = 33.

Accordingly, according to the information setting, the IEEE 1394 module is controlled between the device 1110 and the device 2 120 so that the device 2 120 can receive the output contents of the device 1110.

At this time, if the connection between the device 1 (110) and the device 2 (120) is set, if the third party device 3 (130) wants to see the current output of the device 1 (110) device 3 (130) is currently set The point-to-point connection between the device 1 110 and the device 2 120 is overlaid to establish a point-to-point connection or a broadcast-in connection. When the point-to-point connection between the device 3 130 and the device 1 110 is set to overlap, the content of oPCR of the device 1 110 is oPCR.P-2-P_Connection_Counter = 2, oPCR.Channel_Number = 33, and the device The contents of iPCR of 3 130 are iPCR.P-2-P_Connection_Counter = 1 and iPCR.Channel_Number = 33.

Accordingly, according to the information setting, the IEEE 1394 module is controlled between the device 3 130 and the device 1 110 so that the device 3 130 may receive the output contents of the device 1 110.

If the broadcast-in connection is overlapped between the device 3 (130) and the device 1 (110), the contents of the oPCR of the device 1 (110) is oPCR.P-2-P_Connection_Counter = 1, oPCR.Broadcast_Connection_Counter = 1. , oPCR._Channel_Number = 33, iPCR contents of the device 3 (130) is iPCR.Broastcast_Connection_Counter = 1, iPCR.Channel_Number = 33.

Meanwhile, when a connection is made between the device 1 110 and the device 2 120 through a broadcast connection, the content of oPCR of the device 1 110 is oPCR.Broadcast_Connection_Counter = 1, oPCR._Channel_Number = 33, and device 2 ( The content of iPCR of 120) is iPCR.Broastcast_Connection_Counter = 1 and iPCR.Channel_Number = 33.

Accordingly, a broadcast-out connection is established through the channel 33 to the device 1 110, and a broadcast-in connection is established through the channel 33 to the device 2 120, and according to the information, the device 1 110 and the device are connected. The IEEE 1394 module of 2120 is controlled so that the device 1110 outputs the bitstream to channel 33 and the device 2120 receives the bitstream of channel 33.

At this time, if the device 3 (130) wants to see the current output of the device 1 (110) while the connection between the device 1 (110) and the device 2 (120) is set, the device 3 (130) is the device 1 currently set Overlay or set up a broadcast-in connection to the broadcast-out connection of 110. When the point-to-point connection between the device 3 130 and the device 1 110 is set to overlap, the contents of the oPCR of the device 1 110 are oPCR.P-2-P_Connection_Counter = 1, oPCR.Broadcast_Connection_Counter = 1, oPCR.Channel_Number = 33, and iPCR contents of the device 3 130 are iPCR.P-2-P_Connection_Counter = 1 and iPCR.Channel_Number = 33. If the broadcast-in connection between the device 3 130 and the device 1 110 is established, the content of oPCR of the device 1 110 is oPCR.Broadcast_Connection_Counter = 1, oPCR.Channel_Number = 33, and device 3 ( The content of iPCR of 130) is iPCR.Broadcast_Connection_Counter = 1 and iPCR.Channel_Number = 33.

However, in the related art, a third party device 3 130 uses the bit stream in a state in which a point-to-point connection or a broadcast connection exists between the device 1 110 and the device 2 120. If you want to access it, there is no user control. For example, if device 1 (110) and device 2 (120) are DVCR and DTV in the parent's room and device 3 (130) is the DTV in the child's room, the children control access to the bitstream contents of the VCR watched by their parents. Can not. Therefore, in the related art, the connection between the digital devices is not private and a third party device may access randomly.

An object of the present invention is to prepare a control field set in a specific recording space when establishing a connection between digital devices through a digital interface such as IEEE 1394, thereby accessing a third party device to a bit stream transmitted through this connection. It is to provide a connection management method of a digital interface that can be controlled.

1 illustrates a digital interface connection management method according to the prior art.

FIG. 2A is a detailed view of the oPCR of device 1 of FIG. 1.

FIG. 2B is a detailed view of iPCR of device 2 of FIG. 1.

3 is a block diagram illustrating digital interface connection management according to the present invention.

4A is a detailed view of oPCR of device 1 of FIG. 3.

4B is a detailed view of iPCR of device 2 of FIG. 3.

5 is a flowchart illustrating digital interface connection management according to the present invention.

In order to solve the above technical problem, in the connection management method of the digital interface for controlling the access of another digital device while the source digital device and the sink digital device is connected by a digital interface, Setting a control field in a specific recording space; Marking a control field set in the process when a bitstream transmitted in a state where a connection is established between the source digital device and the sink digital device is private; Determining whether to allow the access by referring to the control field displayed in the process when the other sink digital device accesses the bitstream transmitted through the connection between the source digital device and the sink digital device. Connection management method, characterized in that.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

3 is a block diagram illustrating digital interface connection management according to the present invention.

Referring to FIG. 3, device 1 310, device 2 320, and device 3 330 are connected to an IEEE 1394 bus. Device 1 310 is called a source device (e.g. DVCR), Device 2 320 is called a sink device (e.g. DTV), and Device 3 330 is another sink device (e.g. DTV). A control field is set in a specific storage space of the device 1 310 to control the connection with the device 2 310 and the device 3 330. Herein, the control field is set as a measurement bit field pv in a specific storage space of the oPCR as shown in FIG. 4A.

The flowchart of FIG. 5 will be described with reference to FIGS. 3 and 4A and 4B.

First, in step 510, a control field is set in oPCR, which is a specific memory space of the source device 1 (310).

In step 520, the bitstream transmitted while the point-to-point or broadcast connection is established between the source device 1 310 and the sink device 2 320 is private or in a special case, the special control field is set in the device 1 310. Make a mark. For example, as shown in Fig. 4A, a specific bit field pv is displayed in a specific storage space of the oPCR of the device 1 (310).

Next, when an access request for a bitstream transmitted between the device 1 310 and the device 2 320 is received from the device 3 330 which is a third party device in steps 530 and 540, the device 1 310 of the source device 1 310 is input. Access to the third party device 3 330 is controlled by referring to the control field pv specifically displayed in the specific recording space of the oPCR. The embodiment will be described by dividing the point-to-point connection and the broadcast connection between devices.

First, a point-to-point connection is established between the device 1 310 and the device 2 320 such that the content of the bit stream is extremely private or confidential when the user establishes a connection or while the bit stream is transmitted. Assume that you have selected an option to control access to (330). At this time, the content of oPCR of device 1 310 shown in FIG. 4A is set to oPCR.P_2_P_Connection_Counter = 1, oPCR.Channel_Number = 33, and oPCR.pv = 1. In this situation, when the device 3 330 wishes to overlap this point-to-point connection in order to access the bitstream transmitted through the existing connection, the device 3 330 follows the procedure according to IEC61883 defining the digital interface connection management. That is, the device 3 (330) reads the oPCR of the device 1 (310) (AsyncRead) to obtain the existence of the connection and the channel number used for the connection, and (2) the type of connection that it wants to overlap ( Change the oPCR of device 1 310 and its iPCR according to the point-to-point connection or broadcast connection), and (3) request to change the oPCR of device 1 310 changed to device 1 310 and simultaneously (4) If all of these modification attempts are successful, it determines that the connection is made and controls its own IEEE 1394 module according to this information to control the bitstream. At this time, when the source device 1 310 receives a change request for oPCR from the device 3 330 which is a third party device, the user connected with reference to a specific control field (oPVR.pv) as shown in FIG. 4A. Recognizes that it manages specially and return the error code corresponding to the rejection of the request, or report the access attempt to the existing user to control the access of the bitstream according to the user's permission. Alternatively, when the source device 1 310 receives a read request (AsyncRead) for the oPCR from the device 3 (330), which is a third party device, the device 1 (310) identifies the specific intention of the existing user for the connection related to the oPCR. The device 3 330 may not be accessed by transmitting an error code immediately.

Meanwhile, a broadcast-out connection is established between the device 1 310 and the channel 33 and a broadcast-in connection is established between the device 2 320 and the channel 33, so that the output bit of the device 1 310 is set. Assume that device 2 320 receives the stream. Of course, the user of the device controls the access of the third party device to the content of the bit stream. At this time, the content of oPCR of device 1 310 is set to oPCR.Broadcast_Connection_Counter = 1, oPCR.Channel_Number = 33, oPCR.pv = 1. In this situation, when the device 3 330 accesses a bitstream that is being transmitted through an existing connection, the device 3 330 performs the following procedure according to IEC61883, which defines digital interface connection management. That is, the device 3 (330) (1) reads the oPCR of the device 1 (310) (AsyncRead) to obtain the existence of the connection and the channel number used for this connection, and (2) uses its channel number to determine its own iPCR. After the change, it controls its own bitstream by controlling its IEEE 1394 module. When the source device 1 310 receives a read request (AsyncRead) for the oPCR from the device 3 330, which is a third party device, the source device 1 310 grasps the special intention of the existing user for the connection related to the oPCR. In addition, the device 3 330 may not be accessed by immediately transmitting an error code by rejecting the read request.

The present invention is not limited to the above-described embodiment, and of course, modifications can be made by those skilled in the art within the spirit of the present invention. That is, in the present invention, a specific memory area of the source device 1 310 is separately provided and used as a control field. However, the user's intention may be displayed by using a field previously defined. For example, in case of point-to-point connection, all bits can be displayed as 1 in the value of oPCR.P_2_P_Connection_Counter, and the user's intention is displayed in a specific place in source device 1 310, and then another third party device Refer to this indication when trying to access the associated bit stream.

As described above, according to the present invention, when a connection is established between digital devices through a digital interface such as IEEE 1394, a user of an existing connection may use a special or private bit stream transmitted through the connection. Control access to other third party digital devices.

Claims (3)

In the connection management method of the digital interface for controlling the access of other digital devices while the digital device for the source and the digital device for the sink is connected to the digital interface, Setting a control field in a specific recording space of the source digital device; Marking a control field set in the process when a bitstream transmitted in a state where a connection is established between the source digital device and the sink digital device is private; Determining whether to allow the access by referring to the control field displayed in the process when the other sink digital device accesses the bitstream transmitted through the connection between the source digital device and the sink digital device. Connection management method, characterized in that. The method of claim 1, wherein the control field is set in a specific space of an output plug control register (oPCR) of a digital device. The method of claim 1, wherein the connection of the digital interface is applied in the IEEE 1394 interface standard.