JPH02226828A - Data packet transmission system - Google Patents

Abstract

PURPOSE:To secure data reception confirmation in data packet transmission and to preclude malfunction by adding a bit for requesting a terminal side to send the reception confirmation during polling for soliciting for the reception confirmation when the terminal side performs the reception confirmation every time one block is received. CONSTITUTION:When the system confirms the reception of an outgoing block by the terminal, the ACK bit is added in the transmission solicitation (P#l) to the terminal, i.e., a polling part. Namely, the system side adds the ACK bit in the P#l again unless the system side receives block ACK for a last block to request the terminal to resend the reception confirmation, i.e., 'Send the block ACK again because the block ACK is not received.'. Consequently, the data reception confirmation in the data packet transmission can be secured to preclude malfunction.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to data packet transmission systems, and in particular,
The present invention relates to a data packet transmission system that ensures data delivery confirmation in wireless data packet transmission and prevents malfunctions.

[Prior Art] Figure 2 is a diagram showing a boring method in a conventional data bucket (IE) sending system, in which (a) shows the timing of upstream/downstream data, and (b) shows the timing of upstream/downstream data. Shows slot details.

In FIG. 2(a), P#0 is a call solicitation bowling signal, and P#1 and P#2 are bowling numbers given to specific terminals currently communicating.

Note that in this diagram, two terminals are communicating.

In this figure, the terminal with number i (this i is unrelated to the boring number) makes a call request at the first P#0, and P#l
shows the state in which the terminal given the boring number #1 has transmitted uplink data.

On the other hand, FIG. 2(b) shows the signal structure of the downlink slot in the above-described system, which is divided into a boring section and a data section.

When communicating using such boring, the terminal station is usually in a receiving mode or a transmitting mode. When in reception mode, it monitors the data section to determine whether it is its own data, and when in transmission mode, it monitors the boring section to determine when it should send its own packet.

Next, FIG. 3 is a diagram showing a flow when a base station and a terminal transmit and receive data using the boring method shown in FIG. 1.

In FIG. 3, D(0) to D(7) are units (packets) of downlink wireless data packet transmission, and here, one time is defined as one block. In addition, P#Q is the boring number for terminal α, and P#Q (RVl) is the base station (hereinafter referred to as
It's called a system. ) side takes the transmission right from the terminal.

Now, on the system side, the mth block (D (0) to D
(7) ), an invitation to send (P#Q) indicating the boring number is made to the terminal α in order to know whether the m-th block has been correctly received.

Then, terminal α recognizes that it is its own transmission timing and transmits a delivery confirmation. In other words, when the m-th block arrives normally, the block reception good signal (block Act()
If there is an error, a block reception failure signal (block NAK) is sent.

On the other hand, the system side receives block ACK/NAK from the terminal side.
When it receives, it sends the next data or the data to be retransmitted. That is, if block AC[(, then the next data is sent; if block N A K, the data is retransmitted.

Then, if the m+1th block is the last block,
Block ACK for m+1th block from terminal α
After receiving P#Q, the terminal transmits P#Q to invite transmission of the next uplink data.

A conventional data packet transmission system performs data communication using the procedure described above.

[Problems to be Solved] In the delivery confirmation system in the conventional data packet transmission system described above, if the system side cannot receive the block ACK of the m+1th block, which is the last process,
The system side sends P#Q again. That is, by retransmitting P#Q, an invitation to send a block ACK to the (m+1)th block' is made. However, since the terminal side has already transmitted the block ACK for the (m+1)th block, it recognizes P#Q as an invitation to send uplink data and sends out the uplink data. As a result, the terminal side and the system side recognize the status differently (the system waits for block ACK/NAI (and the terminal sends uplink data), which causes problems in subsequent communication. There was an issue.

The present invention has been made in view of the above problems, and aims to provide a data packet transmission system that ensures data delivery confirmation in data packet transmission and prevents malfunctions.

[Means for Solving the Problems] In order to achieve the above object, a data packet transmission system of the present invention includes a base station that performs transmission control by boring and a plurality of terminals, in which the base station is a block Delivery confirmation reception detection means for detecting whether or not a delivery confirmation has been received after transmitting a unit of data, and boring for inviting transmission when the delivery confirmation reception detection means determines that the delivery confirmation has not been received. and a delivery confirmation transmission sending means for requesting transmission of a delivery confirmation, the terminal further comprising a delivery confirmation sending means for sending a delivery confirmation when the delivery confirmation sending means requests transmission of a delivery confirmation. The composition is as follows.

Under such a configuration, when the terminal side performs delivery confirmation every time one block is received, with n packets as one block, a delivery confirmation is sent to the terminal side during boring to solicit this delivery confirmation. The bit required is granted.

[Example] Hereinafter, the present invention will be explained in detail based on the drawings.

FIG. 1 is a diagram showing a communication flow in a data packet transmission system according to an embodiment of the present invention. The difference from the conventional data packet transmission system shown in Fig. 3 is that when the system confirms the delivery of downlink blocks to the terminal, it includes a delivery confirmation (block A CK) in the invitation to send (P#Q) to the terminal. This is because the ACI (bit) is added to instruct the transmission of the ACI (NAK).

In FIG. 1, when the system side has finished transmitting the m-th block of data, it transmits P#Q (ACI<) with an ACK bit added to request delivery confirmation from terminal α. On the other hand, terminal α has normally received the m-th block, so when it receives P#Q (ACK), block A
Send CK.

Similarly, the system side transmits P#Q (ACK) for the m-th and +1st blocks of the last block, and requests delivery confirmation (block ACK or block N A K'). However, at this time, the system side does not receive the block ACK from the terminal due to some kind of failure, so the system side determines that the transmission confirmation has not been received yet, and sends the delivery confirmation ( P#Q again to request block ACK/NAK)
(ACK) is sent.

On the other hand, terminal α delivers once! i! However, since the bit requesting delivery confirmation is set in the next P#Q (ACIO), it can be seen that the previous delivery confirmation was not received by the system.

Therefore, the delivery confirmation is sent again without transmitting the next data.

As described above, in this embodiment, the ACI< bit is assigned to the boring section when confirming delivery of downlink data. That is, the block ACI for the last block (
is not received by the system side, the system side adds the ACK bit in P#Q again to tell the terminal, ``Block ACK has not been received, so please send block ACK again.'' It is also possible to issue an instruction to resend the delivery confirmation.

[Effects of the Invention] As explained above, the present invention prevents processing from proceeding without receiving a delivery confirmation on the base station side, so there is no difference in status between the base station side and the terminal side. without occurring,
This has the effect of providing a data packet transmission system that can prevent malfunctions.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing a communication flow in a data packet transmission system according to an embodiment of the present invention, FIG. 2(a) is a diagram showing upstream/downstream data timing in a conventional boring method, and FIG. 3 is a diagram showing details of one slot, and FIG. 3 is a diagram showing a flow when data is transmitted and received between a base station and a terminal using the boring method shown in FIG. 2. P#: Solicitation

Claims (1)

[Claims] It is equipped with a base station that performs transmission control by boring and a plurality of terminals, and when the base station and terminals communicate, data communication is performed in units of blocks consisting of a plurality of data packets, and delivery is confirmed in units of blocks. In the data packet transmission system, the base station includes a delivery confirmation reception detection means for detecting whether or not a delivery confirmation has been received after transmitting data in blocks; and a repatriation confirmation transmission requesting means for requesting transmission of a repatriation confirmation during boring to solicit transmission, when the terminal is requested to transmit a delivery confirmation by the repatriation confirmation requesting means. A data packet transmission system comprising a delivery confirmation sending means for sending a delivery confirmation to a data packet transmission system.