KR20010098168A - Device and method for transmitting high speed wireless data using sliding windows flow control in cdma mobile communication system - Google Patents

Abstract

The present invention provides a high-speed wireless data transmission apparatus and method using a sliding window flow control technique in a CDMA mobile communication system, and more particularly, a TCP frame transmitted over a multi-channel during high-speed wireless data transmission irrespective of the reception point. The present invention relates to a high-speed wireless data transmission apparatus using a sliding window flow control technique in a CDMA mobile communication system that reorders sequentially using a sequential signal number carried in a header of a TCP frame and then transmits the data to a higher protocol. According to the high-speed wireless data transmission apparatus and the method using the sliding window flow control technique in the CDMA mobile communication system according to the present invention, the multi-channel to the mobile communication subscriber in a system that can not guarantee the synchronization between channels even between the same link High speed wireless data There are excellent results that can provide the service.

Description

DEVICE AND METHOD FOR TRANSMITTING HIGH SPEED WIRELESS DATA USING SLIDING WINDOWS FLOW CONTROL IN CDMA MOBILE COMMUNICATION SYSTEM}

The present invention relates to a high-speed wireless data transmission apparatus and method using a sliding window flow control technique in a code division multiple access (CDMA) mobile communication system, and more particularly, to be transmitted through a multi-channel during high-speed wireless data transmission. High-speed wireless using sliding window flow control technique in CDMA mobile communication system that reorders the TCP frames sequentially using the sequential signal numbers in the header of the TCP frames regardless of the point of reception A data transmission apparatus and a method thereof are provided.

For reference, the sliding window flow control technique is a transmission control protocol (TCP), which is a protocol used in high-speed wireless data services, and transmits data transmission as a series of data flows rather than as a data transmission block. For example, the transmitting side transmits data as much as the window size informed by the receiving side, and the receiving side transmits the sequential signal number on the header of the data transmitted by the transmitting side.

It means to rearrange them in order using (Sequence Number).

As is well known, subscribers using the CDMA mobile communication system have high speed wireless data communication service with data transmission speed of 64Kbps or more that can send and receive desired information such as internet communication and e-mail transmission through portable terminal as well as voice communication. Is looking forward to possible communication services. As a technology for enabling high-speed wireless data services, future communication technologies that can provide multimedia services such as IS-95B and IS-2000 are gradually being used.

Commercially available wireless data transmission devices in the conventional CDMA mobile communication system comply with the wireless section of IS-95A with speeds of 8Kbps or 13Kbps. Although it is provided, it does not provide an integrated service digital network (ISDN) solution to provide a speed of 64 Kbps or more.

FIG. 1 is a block diagram showing a wireless data transmission apparatus of a channel-to-channel asynchronous system in a conventional CDMA mobile communication system, and FIG. 2 is a block diagram of a wireless data transmission apparatus of a channel-to-channel synchronization system in a conventional CDMA mobile communication system. Shown.

In the conventional CDA mobile communication system, as shown in FIG. 1, the apparatus 1 transmits information simultaneously using adjacent channels in the transmitter 1 (A _0, B _0,... At time t _{0) . ,} N ₀ ), it is not guaranteed that the data arriving at the receiver 2 after the t _t time through the switch 3 is delivered in the order sent by the transmitter 1.

As shown in FIG. 2 in order to solve such inter-channel asynchronousness, the switch of the exchange is required so that data provided through adjacent channels is accurately synchronized between the transmitter 1 and the receiver 2 and the order is guaranteed. (3) should be developed (data of A _0, B _0, ..., N ₀ sent from transmitter 1 at time t ₀ is correctly transmitted to receiver 2 after Tt time). This is not a competitive solution.

Therefore, in the case of transmitting the wireless data using the transmission method using the wireless data transmission apparatus in the conventional CDMA mobile communication system as described above, even if the multi-channel is assigned to the same call for high speed wireless data service, There is a problem in that high-speed wireless data service cannot be provided because channel-to-channel synchronization is not guaranteed.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to provide a high-speed wireless data service through a multi-channel in a system that can not guarantee the synchronization between channels even between the same link. The present invention provides a high-speed wireless data transmission apparatus and method using a sliding window flow control technique in a CDMA mobile communication system for providing a high quality high speed mobile communication service to a mobile subscriber.

In order to achieve the above object, the high-speed wireless data transmission apparatus using the sliding window flow control technique in the CDMA mobile communication system of the present invention converts the wireless data into a TCP frame when wireless data is set by the mobile subscriber. A terminal that outputs continuously through the base station;

A control station for continuously receiving TCP frames from the terminal and simultaneously distributing the TCP frames to multiple channels and outputting them in parallel;

A switching station that receives a TCP frame from the control station through a multi-channel and continuously outputs the FR frame to which a data link connection identifier is assigned; And

It receives the TCP frame continuously from the switching center and temporarily stores it in the internal memory, and then rearranges them in sequence by using the sequential signal number shown in the header of the TCP frame, and transmits them continuously to the higher protocol. .

On the other hand, the high-speed wireless data transmission method using the sliding window flow control technique in the CDMA mobile communication system of the present invention for achieving the above object, the high-speed wireless data is set by the mobile subscriber to the wireless data Converting to a TCP frame and transmitting the same to the control station through the base station;

A second step of the control station continuously receiving the TCP frame from the terminal and simultaneously transmitting the TCP frame to the switching station through the multi-channel;

A third step in which the switching center receives a TCP frame through the multi-channel from the control station and transmits it to the IWF through the FR section to which a data link connection identifier is assigned;

A fourth step of the IWF continuously receiving a TCP frame from the switching center and temporarily storing the TCP frame in an internal memory and transmitting an ACK frame to the terminal; And

And a fifth step in which the IWF rearranges the TCP frames temporarily stored in the internal memory in order and transmits them to a higher protocol.

1 is a block diagram showing a wireless data transmission apparatus of a channel-to-channel asynchronous system in a conventional CDMA mobile communication system;

2 is a block diagram showing a wireless data transmission apparatus of a channel-to-channel synchronization system in a conventional CDMA mobile communication system;

3 is a functional block diagram illustrating a configuration of a high speed wireless data transmission apparatus using a sliding window flow control technique in a CDA mobile communication system according to an embodiment of the present invention;

4 is a block diagram illustrating a network protocol of a high speed wireless data transmission apparatus using a sliding window flow control technique in a CDA mobile communication system according to an embodiment of the present invention;

5 is a TCP frame structure diagram of a high-speed wireless data transmission apparatus using a sliding window flow control technique in a CDA mobile communication system according to an embodiment of the present invention;

6 is a flowchart illustrating a high speed wireless data transmission method using a sliding window flow control technique in a CDA mobile communication system according to an embodiment of the present invention;

7 is an operation flowchart showing in detail the first step of the operation flowchart of FIG. 6 according to an embodiment of the present invention;

8 is a flowchart illustrating a fourth step in detail of the flowchart of FIG. 6 according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

1: transmitter 2: receiver

3: switch 100: terminal

200: control station 210: frame recognition means

300: exchange 400: IWF

Hereinafter, a high-speed wireless data transmission apparatus and method using a sliding window flow control technique in a CDA mobile communication system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a functional block diagram of a high-speed wireless data transmission apparatus using a sliding window flow control technique in a CDA mobile communication system according to an embodiment of the present invention, and is a sliding diagram in a CDM mobile communication system according to an embodiment of the present invention. The high-speed wireless data transmission apparatus using the window flow control technique includes a terminal 100; Control station 200; Switching center 300; And an IWF (Inter Working Function; IWP) 400.

The terminal 100 is a processor used for voice communication as well as Internet connection and e-mail transmission and reception by a mobile communication subscriber. When wireless data is set by a mobile communication subscriber, the terminal transmits the wireless data to a transmission control protocol (TCP). TCP.) The control station through a base station (not shown) after conversion to a frame

It serves to output to (200).

In this case, as shown in FIG. 5, the structure of the TCP frame includes a header, which is a section in which a sequential signal number and a response signal number are loaded, and a data and tail, which is a section in which actual data is loaded, and a structure of the TCP frame. Is done.

In addition, the control station 200 has a call processing control function such as call setup and call cancellation, handoff processing functions related to soft handoff and hard handoff, selector management function, paging support function, overload control function, and system maintenance. A processor that performs a function related to a function of receiving a TCP frame continuously from the terminal 100 and at the same time distributing the TCP frame to the multi-channel appropriately serves to output to the switching center (300).

In this case, the frame recognition unit 210 of the control station 200 recognizes a TCP frame and uses a method of transmitting the TCP frame through a multi channel, and the TCP frame is a lower end point to point protocol. (Hereinafter referred to as PPP).) The protocol is delivered in the form of SDU (Service Data Unit; hereinafter referred to as SDU). Since the PPP frame starts with 7E and ends with 7E, the control station 200 uses this property. The frame recognition means 210 of the serves to distinguish the PPP frame.

In addition, the switching center 300 receives a TCP frame from the control station 200 through a multi-channel and is assigned a FR (Frame Relay) to which a Data Link Connection Identifier is assigned. Through this serves to output the TCP frame to the IWF (400) continuously.

In addition, the IWF 400 continuously receives a TCP frame from the switching center 300 through the FR section to which the data link connection identifier is allocated, and temporarily stores the TCP frame in the internal memory, and then sequentially stores the sequential signal number on the header of the TCP frame. (Sequence Number) is used to reorder in order and to ensure that the order of data is sent correctly to higher protocol.

FIG. 4 is a network protocol used for a high-speed wireless data transmission apparatus using a sliding window flow control technique in a CDA mobile communication system according to an embodiment of the present invention. TCP / IP (Transmission Control Protocol / Internet Protocol) Referred to as TCP / IP), PPP (Point to Point Protocol) (hereinafter referred to as PPP), RLP

(Remote Link Protocol; hereinafter referred to as RLP), ISLP (Inter System Link Protocol; hereinafter referred to as ISLP), FR SVC (Frame Relay Switched Virtual Circuit; hereinafter referred to as FR SVC), and the like.

Next, a high speed wireless data transmission method using a sliding window flow control technique in a CDA mobile communication system according to an embodiment of the present invention using a high speed wireless data transmission apparatus having the above configuration will be described.

6 is a flowchart illustrating a high-speed wireless data transmission method using a sliding window flow control technique in a CDA mobile communication system according to an embodiment of the present invention.

First, when the high-speed wireless data is set by the mobile subscriber, the terminal 100 converts the wireless data into a TCP frame and transmits the wireless data to the control station 200 through the base station (S1).

In this case, the first step S1 operated as described above will be described in more detail with reference to FIG. 7.

First, as shown in FIG. 7, the terminal 100 determines whether the wireless data service is set by the mobile subscriber (S1-1).

In this case, if the wireless data service is not set by the mobile subscriber in step 1-1 (S1-1), the terminal 100 proceeds to the first step S1 again, while the terminal 100 When the wireless data service is set by the mobile subscriber, the terminal 100 converts the wireless data input by the mobile subscriber into a TCP frame and simultaneously converts the TCP frame to the control station 200 through the base station. Transmit (S1)

-2).

Thereafter, the terminal 100 receives an ACK (Ack) in which a response signal is received from the IWF 400.

nowledge; hereinafter referred to as ACK) It is determined whether a frame is received (S1-3).

At this time, when the ACK frame carrying the response signal is received from the IWF 400 in the first 1-3 steps (S1-3), the terminal 100 continuously transmits the next TCP frame through the base station to the control station ( 200) (S1-4).

Here, the terminal 100 confirms the TCP frame received from the IWF 400 by using the response signal carried in the ACK frame transmitted by the IWF 400, and further, by using the window size of the ACK frame Before the terminal 100 receives the ACK frame from the IWF 400, the terminal 100 can know the number of frames that can be sent.

Therefore, when the terminal 100 receives the ACK frame transmitted from the IWF 400 at a time when at least the maximum sliding window size is not used, continuous transmission of the TCP frame is possible.

For example, if the window size of the IWF 400 is 8576 bytes, the terminal

The 100 may continuously transmit up to 16 TCP frames of 536 bytes in a path through a communication path, and then wait for an ACK frame from the IWF 400.

On the other hand, if the terminal 100 does not receive an ACK frame carrying a response signal from the IWF 400 in step 1-3, the terminal 100 is set by the mobile subscriber. After retransmitting the TCP frame to the control station 200 through the base station, the process proceeds to the first step S1-3 (S1-5).

The control station 200 continuously receives a TCP frame from the terminal 100 and simultaneously transmits the TCP frame to the switching center 300 through a multi-channel (S2).

Then, the switching center 300 receives the TCP frame through the multi-channel from the control station 200 and transmits to the IWF 400 through the FR section to which the data link connection identifier is assigned (S3). In this case, when the FR section is used as described above, since the super channel is used between the IWF 400 and the switching center 300, the restriction is not limited to 64 Kbps.

In addition, the IWF 400 continuously receives a TCP frame from the switching center 300 and temporarily stores the TCP frame in an internal memory, and simultaneously transmits an ACK frame to the terminal 100 (S4).

In addition, the IWF 400 rearranges the TCP frames temporarily stored in the internal memory in order and transmits them to the upper protocol (S5).

Meanwhile, a fifth step S5 operated as described above will be described in more detail with reference to FIG. 8.

First, as shown in FIG. 8, the IWF 400 reads a TCP frame temporarily stored in an internal memory (S5-1).

Thereafter, the IWF 400 reads the sequential signal number carried in the header of the TCP frame read from the internal memory and then reads it (S5-2).

Thereafter, the IWF 400 rearranges the TCP frames read in step 5-2 (S5-2) in order (S5-3).

Then, the IWF 400 continuously transmits the rearranged TCP frames to the upper protocol in step 5-3 (S5-4).

As described above, according to the high-speed wireless data transmission apparatus and the method using the sliding window flow control technique in the CDMA mobile communication system according to the present invention, when receiving a high-speed wireless data transmission TCP frame transmitted over a multi-channel Regardless of whether the synchronization between channels is possible even in the same link, it is possible to reorder sequentially using the sequential signal number shown in the header of the TCP frame and transmit it to the upper protocol. There is an excellent effect that can provide a high-speed wireless data service through.

Claims (5)

When wireless data is set by the mobile subscriber, the wireless data is converted into TCP (Trans). mission control protocol) terminal after converting the frame and outputs continuously through the base station; A control station for continuously receiving TCP frames from the terminal and simultaneously distributing the TCP frames to multiple channels and outputting them in parallel; Switching station that receives TCP frame from the control station through multi-channel and continuously outputs through FR (Frame Realy) section to which data link connection identifier is assigned ; And After receiving TCP frames continuously from the switching center and temporarily storing them in the internal memory, and then rearranging them sequentially using the sequential signal numbers in the header of the TCP frames, and then sequentially transmitting them to the upper protocol. A high speed wireless data transmission apparatus using a sliding window flow control technique in a configured CDA mobile communication system. A first step of converting the wireless data into a TCP frame and transmitting the wireless data to the control station through the base station as the terminal sets the high speed wireless data by the mobile subscriber; A second step of the control station continuously receiving the TCP frame from the terminal and simultaneously transmitting the TCP frame to the switching station through the multi-channel; A third step in which the switching center receives a TCP frame through the multi-channel from the control station and transmits it to the IWF through the FR section to which a data link connection identifier is assigned; A fourth step of the IWF continuously receiving a TCP frame from the switching center and temporarily storing the TCP frame in an internal memory and transmitting an ACK (Acknowledge) frame to the terminal; And And a fifth step in which the IWF rearranges the TCP frames temporarily stored in the internal memory in order and transmits the data to the upper protocol. 5. The method of claim 2, The first step may include: a first step of determining, by the terminal, whether a wireless data service is established by a mobile subscriber; If the wireless data service is not set up by the mobile subscriber in step 1-1, the terminal proceeds to the first step again. If the wireless data service is set up by the mobile subscriber, the terminal moves. A first and second step of converting wireless data input by the communication subscriber into a TCP frame and transmitting the same to the control station through a base station; A first step 1-3 in which the terminal determines whether an ACK frame carrying a response signal has been received from the IWF; And If the ACK frame carrying the response signal is received from the IWF in steps 1-3, the terminal further includes steps 1-4 of continuously transmitting a next TCP frame to the control station through a base station; A high speed wireless data transmission method using a sliding window flow control technique in a CDA mobile communication system. The method of claim 3, wherein If the terminal does not receive the ACK frame carrying the response signal from the IWF in step 1-3, the terminal retransmits the TCP frame set by the mobile subscriber to the control station and proceeds to step 1-3. A high-speed wireless data transmission method using a sliding window flow control technique in a CDMA mobile communication system, further comprising steps 1-5. The method of claim 2, The fifth step may include a fifth step in which the IWF reads a TCP frame temporarily stored in an internal memory; A fifth step of reading and reading a sequential signal number carried in a header of a TCP frame read from an internal memory by the IWF; Step 5-3 in which the IWF reorders the TCP frames read in step 5-2; And High speed using the sliding window flow control method in the CDMA mobile communication system further comprises the step 5-4 of the IWF to continuously transmit the rearranged TCP frame to the upper protocol in step 5-3 Wireless data transmission method.