JPS61129931A - Time division multiple access communication system - Google Patents

Abstract

PURPOSE:To improve the transmission efficiency by using a one-unit data burst transmitting a data of one unit and an n-unit data burst transmitting plural (n+m)-unit data of one kind or over. CONSTITUTION:A one-unit data burst No.1 consists of a guard time GT, a preamble word PRW, a one-unit data DT and a post amble PA. Figure (2) shows an (n+m)-unit data burst, where a 6-unit data burst (n=5, m=1) is shown. Thus, the frame efficiency is improved by using a terminal station device with comparatively simple constitution, the flexibility at channel setting is kept and a TDMA communication system with improved transmission efficiency is realized.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to time division multiple access communication (TDMA communication) systems. The method according to the present invention is used for TDMA communication using a satellite.

Problems to be solved by the prior art and the invention are generally T.
In the DMA communication system, the burst configuration is as shown in FIG. 3, and the traffic burst length or data burst length excluding reference busts, signaling bursts, etc. transmits one unit of data, for example, 64 kbps data. TDMA frame format using fixed-length data bursts fixed to one type that can be used
- (SCPB method, i.e. Single Channel
In the el per burst method), as shown in FIG. 4, the traffic burst length is variable depending on the size of the traffic. TDM using variable length data bursts
There are A-frame frame format types.

In Figures 3 and 4, GT is guard time, PRW
is the preamble word, DT is the data, PA is the postamble, and CH is the variable length data.

TDMA using fixed length data bursts shown in Figure 3
Frame formats have a simple terminal device configuration, but because the preamble portion occupies a large proportion of one frame, the frame efficiency, defined as the proportion of actual data in one frame, is low. There is a problem.

On the other hand, the TDMA frame format using variable-length data bursts shown in Fig. 4 has high frame efficiency, but because it handles cases where the burst length changes from moment to moment due to channel increases or decreases, the burst There is a problem that the transmitting/receiving position must be changed at the same time for all stations in the system, and the configuration of the terminal equipment becomes complicated.

In view of the problems in the conventional type described above, the purpose of the present invention is to
The object of the present invention is to realize a TDMA communication system in which frame efficiency is improved, flexibility in channel setting is maintained, and transmission efficiency is improved using a terminal device with a relatively simple configuration.

Means and Effects for Solving the Problems The present invention includes a reference burst for managing time division multiple access communication (TDMA communication), a data burst for transmitting traffic data, etc. There are at least two types of data bursts that transmit data, one of which is a 1-unit data burst that transmits 1 unit of data, and the other is a data burst that transmits a predetermined number of "n+m" data.
J (n, m are positive integers) unit data burst of one or more types that transmit data in units of "nJ",
Similarly, the length represented by the number of symbols is the sum of the burst length including the preamble word and postamble word of an nJ unit data burst and the guard time, and the length of the 1 unit data burst including the preamble word and postamble word plus the guard time. select an integer "nJ" times the length represented by the number of symbols plus the number of symbols, and select an integer "nJ" times the length of the time slot that accommodates one unit data burst on the frame. A time division multiple access communication system is provided which is characterized by being accommodated within a double length time slot.

In the time division multiple access Vt communication system according to the present invention, 2
In one of the types of data bursts, one unit of data is transmitted by a one-unit data burst, and in the other one, one or more types of plural 'n+mJ unit data are transmitted by plural 'nJ unit data bursts. The length of an nJ unit data burst is selected to be an integer nJ times (or less than an integer nJ times) the length of a 1 unit data burst, and when using a data rate of n+IJ units or more, the length of the burst Use one burst.

Embodiment Time division multiple access communication (TDM) as an embodiment of the present invention
The TDMA burst frame format in the A communication system is shown in FIG.

In FIG. 1, (1) indicates a burst for one unit of data. (2) indicates a burst for n+mJ unit data, and here n-5, m=1, indicates a 6 unit data burst. In (1) of Fig. 1, the first time slot (Nll) is Guard time GT, preamble word PRW, 1 unit data DT, and postamble P
Consists of A. Guard time GT is a margin time for preventing burst collision without actually emitting radio waves. Note that the post angle PA may not be necessary. Note that since data generally consists of symbols, the number of symbols determines the data length.

An example of a TD?IA frame using the frame format shown in No. 111 (++, (2)),
A case in which only unit data bursts are used is shown in FIG. 2+11. Another example of a TDMA frame using the frame format shown in FIGS. 1 (1) and (21) is shown in FIG. is shown.

That is, in the format shown in Figure 2,
At least two types of fixed-length bursts are used: a one-unit burst and a burst with a data length that is an integer nJ times the data length plus the guard time (in this example, n=5).

Using this formant, when using a data rate of n+IJnl or more, use n-unit bursts with a long burst length.

For example, when sending n+2J units of data, one n unit burst and two 1 unit bursts are used.

In the format of FIG. 2(2), the n unit burst occupies n unit time slots.

In the format of Figure 2 (1), 5 units of data is transmitted in n (n = 5 in this example) unit time slots (UTSXn), but in the format of Figure 2 (2), 5 units of data are transmitted in 5 unit time slots. Equivalent portion (UTS
6 ("nlm; m=1 in this example) units of data can be transmitted in Xn).

In Figure 1 (1), when one unit data length is 5UDL and the unit time slot length is UTS, Figure 2 (2
), the n unit time slot length U T S (nl
is written below based on the format shown in FIG. 1(2).

u'rs(n) = (nlm)
) Based on the format of FIG. 2 (1), the following holds true.

UTS(n)=nX ((GT+PRW+PA)+(
Number of symbols in one unit of data)) --- (2) From the above equations (1) and (2), the following holds true.

(number of symbols) ) −(GT+, PRw+PA) (〃) −・−・・(3) Equation (3) above calculates GT+PR from the normally considered preamble length, assuming that the number of symbols in one unit of data = 640.
This shows that there is a solution: W+PA=iso, n=5, m=1. This means that by using the burst array in the format shown in Figure 1, it is now possible to transmit 6 units of data in a time slot where previously only 5 units of data could be transmitted. do.

In this way, in the formats of Figures 1 and 2,
There are two types of data bursts.

One is a 1 unit data burst (Fig. 1 (1)) that transmits 1 unit of data, and the other is a multiple nJ unit data burst (Fig. 1 (2)) that transmits data of multiple n+ml vehicle positions. ).

The length UTSfnl, expressed in symbols, is the sum of the burst length including the preamble word and postamble word of a multi-unit data burst, plus the guard time, and the length UTSfnl, which is the sum of the burst length including the preamble word and postamble word, plus the guard time. It is chosen to be an integer n times the length UTS expressed in number of symbols.

Note that the above-mentioned multiple is not necessarily limited to an integral number n times, but may be an integral number n times or less. however,
Even in that case, a time slot that accommodates multiple n+m J unit data bursts.

The data is kept as an integer 'nJ times the UTS.

Effects of the Invention According to the present invention, using a terminal device with a relatively simple configuration,
TDM with improved frame efficiency, maintaining flexibility in channel configuration, and thus improving transmission efficiency
A policy method can be realized.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing a TDMA burst frame format showing the operation status of a TDMA communication system as an embodiment of the present invention, FIG. 2 is a diagram showing a TDMA burst frame format based on the format of FIG. 1, FIGS. 3 and 4 are diagrams showing conventional TI) MA/N'-ST frame formats. GT: Guard Time, PRW: Preamble Word, DT: 1 Unit Data, PA: Bost Ampoule, 5IJDL: Single Unit Data Length, UTS: Unit Time Slot.

Claims (1)

[Claims] There are at least two types of data bursts that transmit traffic information, including a reference burst for managing time division multiple access communication (TDMA communication) and a data burst for transmitting traffic data. One is a 1-unit data burst that transmits 1 unit of data, and the other is a predetermined number of "n+m" (n
, m is a positive integer) units of data, the burst length and guard time including preamble words and postamble words of the multiple "n" unit data bursts. Similarly, the length expressed in the number of symbols plus the guard time is multiplied by an integer "n" characterized in that the burst of the plurality of "n" units of data is accommodated in a time slot whose length is an integer "n" times the length of a time slot accommodating a single unit of data burst on a frame; Time division multiple access communication method.