JP2003124940A - Wireless lan system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid a useless power consumption of AP and ST in a radio communication of one AP with a plurality of STs by the polling system. SOLUTION: CPU 1g of an AP1 receives data from a network 5 via a first controller 1a, and an RTC 1g1 built in the CPU 1g calculates the quantity of received data while the relation of the range of the data quantity with the polling time interval is previously tabulated and stored in a memory 1c. The CPU 1g collates the table with the calculation result to determine the polling time interval. Based on this determination, a modulator 1d digitally modulates and transmits a signal, a receiver 2b in ST2 receives the signal, a demodulator 2c demodulates and sends the data to a detector 2d, and the detector 2d detects the polling time interval from the demodulated data and stores it in a memory 2e. CPU 2f sets the receiver 2b and the demodulator 2c in standby mode, except during receiving data by itself.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless LAN system, and more particularly to a wireless LAN system in which one AP (access point) and a plurality of STs (stations) wirelessly communicate by a polling method. The present invention relates to prevention of unnecessary power consumption of AP and ST by optimization.

[0002]

2. Description of the Related Art As shown in FIG. 1, one AP 1 and a plurality of STs 2, 3 and 4 are provided. The AP 1 receives data via a network 5, and the received data is transmitted to the ST 1.
Wireless L to be distributed to 2, 3 and 4 by polling method
There is an AN system. In the case of this polling method, AP
1 transmits a beacon at a constant interval time, sets reception timing for each ST by the beacon, and distributes data to each ST 2, 3, 4 between each beacon by time division. Each ST 2, 3 and 4 receives data in its assigned time zone using the beacon as a control signal. This situation is shown in FIG. 4, which shows data distribution S
T has two stations, ST-a and ST-b.

However, the amount of data to be distributed is not always constant and varies depending on the time zone and each ST. In FIG. 4, the amount of data is large in both ST-a and ST-b in the time zone Ta, the data for ST-a is almost halved at the time Tb, and there is no data to be distributed in ST-b.
This is an example in which there is no data to be distributed in both ST-a and ST-b at time Tc. In this case, S at time Ta
Both T-a and ST-b communicate with each other for the allotted time, but at time Tb, communication time at ST-a is halved, communication time at ST-b becomes zero, and at time Tc. The communication time is zero in both ST-a and ST-b. Even in such a state, each ST normally operates and consumes unnecessary power. Furthermore, A
P always transmits a beacon at a constant time interval (Ts) regardless of the amount of data to be distributed, and in this respect as well, it is useless power consumption.

[0004]

As described above, the conventional wireless LAN system has a problem that it consumes unnecessary power. In view of the above problems, the present invention is
An object of the present invention is to provide a wireless LAN system in which the polling interval time is optimized according to the amount of data distributed to each ST and unnecessary power consumption in the AP and each ST is prevented.

[0005]

In order to achieve the above object, the present invention comprises one AP and a plurality of STs.
In a wireless LAN system configured to receive data via a network and deliver the received data to the ST in a polling method, the AP polls the AP to determine a polling interval time according to the amount of the received data. An interval time determining means is provided to provide a wireless LAN system that distributes the received data and the data of the determined polling interval time to each ST based on the polling interval time determined.

Further, the ST detects the determined polling interval time, sets the receiving means to a normal receiving state during its own receiving period within the detected polling interval time, and except the above receiving period. A setting means for setting the receiving means to the standby state is provided.

Further, the polling interval time determining means includes a CPU for calculating the amount of data received via the network, a controller for controlling the modulation unit under the control of the CPU, and a polling interval time corresponding to the data amount. And a memory unit in which is stored in advance.

Further, the relationship between the amount of data stored in the memory unit and the polling interval time is such that the range of the data amount and the polling interval time are associated with each other, and the polling interval time becomes larger as the data amount increases. shorten.

The calculation of the amount of received data is based on counting the number of bits of the received data.

In the setting means, a detector for detecting the polling interval time from the data received by the receiver, a memory portion for storing the polling interval time detected by the detector, the detector and the memory portion. C to control and
Composed of PU and.

When the detected polling interval time is changed, the data in the memory section is updated to the changed data.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings based on examples. 1 is a block diagram of a wireless LAN system for explaining the present invention, FIG. 2 is a block diagram of essential parts showing an embodiment of an AP and ST according to the present invention, and FIG. 3 is a polling explanatory view for FIG. Figure 1
In, 1 is AP, 2, 3 and 4 are ST-a (hereinafter,
ST2), ST-b (hereinafter, ST3) and ST-n (hereinafter, ST4) and 5 are networks (wired). The AP1 receives data from the wired network 5, and the received data is transmitted to the required ST2 by the polling method.
Deliver to ST3 or ST3. In FIG. 2, the same parts as those in FIG. 1 are designated by the same reference numerals. AP1 in FIG.
1a is a first controller, 1b is a second controller, 1c is a memory unit, 1d is a modulator, 1e is a transmitter, 1f is a transmitting antenna, 1g is a first controller 1a, a second controller 1b and It is a CPU that controls the memory unit 1c. In ST2 of FIG. 2, 2a is a receiving antenna, 2b is a receiving unit, 2c is a demodulating unit, 2d is a detecting unit, 2e is a memory unit, 2f is a receiving unit 2b, a demodulating unit 2c, a detecting unit 2d and a memory unit 2e. Is a CPU for controlling the. Although the reception function of AP1 and the transmission function of ST2 are not shown in FIG. 2,
These are provided in the actual configuration.

Next, the operation of AP1 and ST2 of FIG. 2 will be described. In AP1, the CPU 1g controls the first controller 1a to receive data from the network 5. CPU 1g has a built-in RTC (Real Time Clock)
1g1 calculates the amount of data received from the network 5. This RTC has a counter function,
The amount of data is obtained by counting the number of bits of received data. Based on the above calculation result, the CPU 1g determines an appropriate polling interval time. Here, the “appropriate polling interval time” means the time of the polling interval when the number of times of polling is reduced without lowering the data distribution rate. Therefore, the relationship between the range of the amount of data calculated by the RTC 1g1 and the polling interval time is tabulated in advance and stored in the memory unit 1c, and the table and the RT
The polling interval time is determined by collating with the calculation result of C1g1.

The CPU 1g controls the second controller 1b so as to set the polling interval time determined above. Digital modulation according to a predetermined method is performed in the modulator 1d via the second controller 1b controlled in the same manner. At the time of the modulation, the CPU 1g sends the data received from the network 5 and the data of the determined polling interval time as auxiliary information to the modulation unit 1d via the second controller 1b. The signal from the modulation unit 1d is amplified in the transmission unit 1e. Predetermined processing such as is performed, and the signal is transmitted from the transmission antenna 1f. In addition,
The second controller 1b, the memory unit 1c and the CP described above
The constituent part consisting of U1g was used as the polling interval time determining means. The reception unit 2b receives the transmission signal via the reception antenna 2a of ST2. The received signal is data-demodulated by the demodulator 2c, and the demodulated data is sent to the detector 2d. Same detection unit
2d detects the polling interval time from the demodulated data. The data of the detected polling interval time is stored in the memory unit 2e. After the storage, if the polling interval time from AP1 is changed, the memory is updated (rewritten) to the new polling interval time of the change.

The CPU 2f sets the reception unit 2b and the demodulation unit 2c in a normal operating state (hereinafter, normal mode) until the polling interval time is stored in the memory unit 2e, and after the storage, the self receives data. Outside the period, the receiver 2b and the demodulator 2c are set to the standby state (hereinafter, standby mode),
Set to the normal mode during the period when data is received. In addition,
The standby mode period is determined by the polling interval time and its own reception timing based on the received beacon. In addition, the detection unit 2d, the memory unit 2e, and the CPU described above.
The component part consisting of 2f was used as the setting means. Below, CPU
2f is appropriately switched to the normal mode or the standby mode according to the polling interval time.

FIG. 3 shows the relationship between the polling interval time and the data amount described above. In the same figure, as in the case of FIG. 4, ST for data distribution is two stations of ST2 and ST3, and T1, T2 and T3 in the figure are beacon transmission intervals (that is, polling interval times. As can be understood from the above, T1 <T2 <T3, where T1 is the polling interval time during which the data amount is large, T2 is the time period during which the data amount is decreasing, and T3 is the polling period during which the data amount is decreasing. By setting the polling interval time as described above, the beacon becomes a normal interval at time T1 and both ST2 and ST3 communicate with each other during the allotted time. At time T2, the beacon interval becomes longer, and ST2 and ST3
In both cases, the communication time is relatively reduced, and at time T3, the beacon interval is further lengthened, and the communication time is further reduced in both ST2 and ST3. In addition, both ST2 and ST3 receive no data (ta, tb, t
During periods other than c and td), the standby state described above is set, and the normal mode is set only when data is received. This allows AP1
Also, it is possible to avoid unnecessary power consumption in each of ST2 and ST3.

[0017]

As described above, according to the present invention, A
The P side changes the polling interval time according to the amount of distribution data, and the ST side puts the receiving function in the standby state except during the period in which it receives itself, so that unnecessary power consumption is avoided in the AP and each ST, thus saving power. It becomes possible to use electricity.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a wireless LAN system for explaining the present invention.

FIG. 2 is a block diagram of main parts showing an embodiment of AP and ST according to the present invention.

FIG. 3 is an explanatory diagram of polling related to FIG. 2;

FIG. 4 is an explanatory diagram of polling related to a conventional technique.

[Explanation of symbols]

1 AP (access point) 1a First controller 1b Second controller 1c memory section 1d modulator 1e transmitter 1f transmitting antenna 1g CPU 2, 3, 4 ST (station) 2a receiving antenna 2b Receiver 2c demodulator 2d detector 2e Memory section 2f CPU 5 network

Claims (7)

[Claims] 1. An AP (access point) and a plurality of STs (stations), wherein the AP receives data via a network and distributes the received data to the ST by a polling method. Become wireless L
In the AN system, the AP is provided with polling interval time determining means for determining a polling interval time according to the amount of received data, and the received data and the data of the determined polling interval time are based on the polling interval time determined. Is distributed to each of the STs. 2. The ST detects the determined polling interval time, sets the receiving means to a normal reception state during its own reception period within the detected polling interval time, and except the reception period. 2. The wireless LAN system according to claim 1, further comprising setting means for setting the receiving means in a standby state. 3. The polling interval time determining means calculates the amount of data received via the network C
2. The wireless LAN system according to claim 1, wherein the wireless LAN system comprises a PU, a controller that controls a modulator under the control of the CPU, and a memory that stores a polling interval time corresponding to the data amount in advance. . 4. The relationship between the data amount stored in the memory unit and the polling interval time is such that the range of the data amount and the polling interval time are associated with each other, and the polling interval time is set to increase as the data amount increases. The wireless LAN system according to claim 3, wherein the wireless LAN system is shortened. 5. The wireless LAN system according to claim 3, wherein the calculation of the amount of received data comprises counting the number of bits of the received data. 6. A detection unit for detecting the polling interval time from the data received by the receiving unit, the setting unit comprising:
A memory unit that stores the polling interval time detected by the detection unit, and a CPU that controls the detection unit and the memory unit
3. The wireless LA according to claim 2, characterized in that
N system. 7. The wireless L according to claim 6, wherein when the detected polling interval time is changed, the data in the memory unit is updated to the changed data.
AN system.