KR101631498B1 - Apparatus and method for using low-rate wakeup preamble in transmitter and receiver - Google Patents

Abstract

And a transmitting and receiving apparatus and method using a low-rate wake-up preamble. The proposed transmitting device generates and transmits a physical layer frame including a low rate wakeup preamble to reduce power consumption of idle listening of the receiving device. Then, the proposed receiving apparatus keeps the idle listening state sampling at a low rate. When detecting a low rate wakeup preamble, it switches to full rate sampling and receives a physical layer frame.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a low-rate wake-up preamble and a low-rate wakeup preamble.

Described below are frame formats for reducing power consumption of idle listening and frame pockets using low rate wakeup preambles.

Idle listening samples the channel to receive the expected frame, but the actual frame is not being received. For IEEE 802.11a with a bandwidth of 20Mhz, it usually performs 40 * 10 ⁶ samples per second. In most LANs, the channel is shared with other nodes, and in many cases the traffic pattern can not be predicted, which has been regarded as an important power source for wireless communications.

When the low power algorithm is not supported, the receiving device maintains an idle listening state in preparation for frame transmission from the transmitting device. In this case, the receiver may have the smallest transmission latency, but the receiver continuously consumes energy due to idle listening regardless of the data.

The transmitting apparatus includes a physical layer frame generating unit for generating a physical layer frame by inserting a physical layer (PHY) header into a MAC layer frame, and a narrowband header sampled at a low rate to the physical layer frame And a narrowband header inserting section for inserting the narrowband header.

In this case, the control unit may determine whether insertion of the narrowband header is required, determine whether to insert the narrowband header, and control the narrowband header insertion unit.

At this time, the controller may control to insert the narrowband header when it is determined that the receiver is in an idle listening state sampling at a low rate.

In this case, the narrow-band header may be a low-rate wake-up preamble generated by extending the signal of the physical layer header and reducing the bandwidth for transmitting the physical layer header.

The receiving apparatus includes a rate control unit that samples at a low rate in an idle listening state and controls a sampling rate to sample at a full rate when receiving a physical layer frame, A low-rate wake-up preamble in the digital signal sampled at a low rate and converted by the digital conversion unit into a digital signal; And a preamble detection unit for detecting the preamble.

At this time, the low-rate wake-up preamble may be a narrow-band header that is generated by extending the signal of the physical layer header and reducing the bandwidth for transmitting the physical layer header.

At this time, if the preamble detection unit detects the low-rate wake-up preamble, the rate control unit may control sampling at the full rate.

At this time, if the rate controller detects completion of preamble reception, the rate controller may control to sample at the low rate.

At this time, the rate control unit may continue the sampling operation of the full rate in preparation for reception of consecutive frames through a more bit indicating the presence of the next physical layer frame, It is possible to detect completion of the full rate sampling operation.

The physical layer processor may further include a physical layer processor for processing the physical layer frame, and the digital converter may transmit the digital signal sampled at the full rate to the physical layer processor.

A method for transmitting a frame including a low rate wakeup preamble includes the steps of generating a physical layer frame by inserting a physical layer (PHY) header into a MAC layer frame, and transmitting the physical layer frame with a low rate And inserting a narrowband header to be sampled into the narrowband header.

The method may further include determining whether insertion of the narrowband header is necessary before inserting the narrowband header, and determining whether to insert the narrowband header.

The step of determining whether to insert the narrowband header may determine to insert the narrowband header if it is determined that the receiving apparatus is in an idle listening state sampling at a low rate.

In this case, the narrow-band header may be a low-rate wake-up preamble generated by extending the signal of the physical layer header and reducing the bandwidth for transmitting the physical layer header.

The method may further include sampling and transmitting a control frame indicating that a physical layer frame in which the narrowband header is inserted is transmitted at a full rate prior to transmitting the physical layer frame in which the narrowband header is inserted.

A method of receiving a frame including a low-rate wake-up preamble includes the steps of sampling an analog signal received in an idle listening state at a low rate and converting the analog signal into a digital signal, Detecting a low rate wakeup preamble in the converted digital signal; and sampling the received analog signal at a full rate upon sensing the low rate wakeup preamble.

At this time, the low-rate wake-up preamble may be a narrow-band header that is generated by extending the signal of the physical layer header and reducing the bandwidth for transmitting the physical layer header.

The method may further include sampling the received analog signal at the full rate and converting the sampled analog signal into a physical layer frame when the low rate wakeup preamble is detected.

At this time, if it is detected that the sampling operation of the full rate is completed, it may further include converting the sampling rate to be sampled at the low rate.

At this time, the completion of the sampling operation of the full rate may be detected through a more bit indicating the presence of a next physical layer frame or may be detected when a physical layer frame is not received for a preset time.

When a transmitting apparatus generates and transmits a physical layer frame including a low-rate wake-up preamble, the receiving apparatus that has kept the idle listening state sampling at a low rate detects a low-rate wakeup preamble and switches to full- The present invention relates to a transmitting and receiving apparatus and method for receiving a physical layer frame sampled by a receiving apparatus, and can reduce power consumption of idle listening in a receiving apparatus.

1 shows a configuration of a transmitting apparatus for generating a frame including a low rate wakeup preamble according to a proposed embodiment,
2 shows a configuration of a receiving apparatus for receiving a frame including a low rate wakeup preamble according to the proposed embodiment,
FIG. 3 shows a structure of a frame including a low-rate wake-up preamble according to the proposed embodiment,
4 is a diagram illustrating a structure of an IEEE 802.11 frame to which a low rate wakeup preamble is applied according to the proposed embodiment,
5 is a diagram illustrating an example of transmitting / receiving according to the proposed wakeup protocol,
FIG. 6 is a diagram illustrating an example of transmission / reception considering both a legacy receiving apparatus and a proposed receiving apparatus according to a proposed wakeup protocol,
FIG. 7 is a flowchart illustrating a process of generating and transmitting a frame including a low-rate wake-up preamble according to a proposed embodiment,
8 is a flowchart illustrating a process of receiving a frame including a low-rate wake-up preamble according to a proposed embodiment.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a frame format including a low-rate wakeup preamble generated in a transmitting apparatus for reducing power consumption of idle listening of a receiving apparatus, and to an apparatus and method for transmitting and receiving data using a low-rate wakeup preamble will be.

1 is a diagram showing a configuration of a transmitting apparatus for generating a frame including a low rate wakeup preamble according to a proposed embodiment. 1, a transmitting apparatus 100 includes a MAC frame generator 110, a physical layer (PHY) frame generator 120, a narrowband header inserter 130, a controller 140, And a transmission unit 150.

The MAC frame generation unit 110 generates a MAC frame and transmits the generated MAC frame to the PHY frame generation unit 120. The PHY frame generation unit 120 generates a PHY frame by adding a PHY header to the received MAC frame.

The narrowband header inserter 130 inserts a narrow band header into the PHY frame generated by the PHY frame generator 120 under the control of the controller 140. A narrow band header is a PHY header that is sampled at a low rate. The narrowband header is a preamble generated by extending the signal of the PHY header included in the PHY frame and reducing the bandwidth for transmitting the PHY header.

The control unit 140 determines whether a narrowband header is required or not, and controls the narrowband header inserter 130 to insert a narrowband header if necessary.

If the control unit 140 determines that the receiving apparatus is in an idle listening state sampling at a low rate, it determines that the collusion header is necessary.

The transmitting unit 150 transmits the PHY frame in which the narrowband header is inserted to the receiving apparatus.

The PHY frame in which the narrowband header is inserted is configured as shown in FIG. 3 below.

FIG. 3 is a diagram illustrating a structure of a frame including a low-rate wake-up preamble according to the proposed embodiment. Referring to FIG. 3, a PHY frame 300 in which a narrowband header is inserted is a form in which a PHY frame 310 including a PHY header 314 and data 316 is combined with a narrowband header 312.

The PHY header 314 and data 316 are general components of the PHY frame and are comprised of a full band 334 and are sampled at full rate 324. [

The narrowband header 312 corresponding to the low-rate wakeup preamble is composed of a narrow band 332 and is sampled at a low rate 322.

The narrowband header 312 is used as a preamble for detecting a frame in the receiving apparatus according to the proposed embodiment. The narrowband header 312 is sampled low enough to not be detected at full-rate sampling at the receiving device. The minimum length of the narrowband header 312 is the sum of the minimum length for detection and the required length for switching to the full rate. In addition, the length of the narrowband header 312 may be set differently according to the energy consumption and the channel utilization rate.

Hereinafter, an example in which a low-rate wake-up preamble is applied to the frame structure of IEEE 802.11 will be described with reference to FIG.

FIG. 4 is a diagram illustrating a structure of an IEEE 802.11 frame to which a low-rate wake-up preamble according to the proposed embodiment is applied.

The conventional IEEE 802.11 frame 410 includes a Short Training Field (STF) 411, a Long Training Field (LTF) 412, a Signal Field (SIG) 413, And a data field 414.

The STF 411 is a signal for signal detection, automatic gain control, prediction of a coarse frequency offset, diversity selection, and time synchronization. The LTF 412 is a signal for predicting a channel and a fine frequency offset. The SIG 413 is a signal for providing a transmission rate and a frame length. The data field 414 contains the actual data to be transmitted. At this time, an additional preamble may be placed in the data field 414.

The frame 420 in which the narrowband STF is inserted according to an embodiment of the present invention is configured to further include a narrow band STF 421 in the IEEE 802.11 frame 410. The narrowband STF 421 expands the signal of the existing STF 411 by three times and uses a bandwidth of 1/3.

Since the frame 420 in which the narrowband STF 421 is inserted includes the same STF 411 as the existing frame, the legacy receiving apparatus can not detect the narrowband STF 421, It is possible to detect the frame 420 in which the band STF is inserted.

The frame 430 including the narrow-band STF and the reduced STF, which is a frame according to another proposed embodiment, includes a narrow-band STF 421, a shortened-short training field (S-STF) 431, An LTF 412, a SIG 413, and a data field 414.

The S-STF 431 is a field missing information for signal detection in the existing STF 411. The S-STF 431 is a signal for automatic gain control, prediction of a coarse frequency offset, diversity selection, and time synchronization.

The frame 430 including the narrowband STF and the reduced STF does not contain information for detection in the S-STF 431 transmitted at the full rate and is not detected in the legacy receiving apparatus.

2 is a diagram illustrating a configuration of a receiving apparatus that receives a frame including a low-rate wake-up preamble according to a proposed embodiment.

2, the receiver 200 includes a receiver 210, a digital converter 220, a preamble detector 230, a rate controller 240, a PHY frame processor 250, (MAC) frame processing unit 260.

The receiving unit 210 includes a front end unit and a filter, and converts the high frequency band signal that has passed through the wireless channel into a baseband signal and outputs the baseband signal.

And provides the analog signal to the digital conversion unit 220.

The digital converter 220 samples the analog baseband signal from the receiver 210 at a low rate or a full rate under the control of the rate controller 240 and converts the sampled analog baseband signal into a digital signal.

The digital converter 220 transmits the digital signal sampled at a low rate to the preamble detector 230. The digital conversion unit 220 transmits the digital signal sampled at a full rate to the PHY frame processing unit 250.

The preamble detection unit 230 determines whether the digital signal received from the digital conversion unit 220 is a narrowband header that is a preamble sampled at a low rate.

When the preamble detection unit 230 detects the narrowband header, the rate control unit 240 controls the digital conversion unit 220 to sample at a full rate. When the rate control unit 240 detects completion of the full rate sampling operation, the rate control unit 240 controls the digital conversion unit 220 to sample at a low rate. The rate control unit 240 checks the completion of the full rate sampling operation through a more bit indicating that the next received frame exists or detects that the full rate sampling operation is completed when the frame is not received for a preset time can do.

The PHY frame processing unit 250 extracts a MAC frame from the PHY frame and outputs the extracted MAC frame to the MAC frame processing unit 250. [ (260).

Upon receiving the MAC frame, the MAC frame processing unit 260 extracts data from the MAC frame through the MAC layer process and outputs the extracted data.

5 is a diagram showing an example of transmitting / receiving according to the proposed wakeup protocol.

In FIG. 5, the height of the dotted line indicates the degree of the sampling rate, and a low dotted line indicates low rate sampling and a high dotted portion indicates full rate sampling.

Referring to FIG. 5, the transmitting apparatus 100 transmits a PHY frame 300 in which a narrowband header including a narrowband header 312 and a PHY frame 310 is inserted.

Then, the receiving apparatus 200 proceeds to sampling at a low rate at which only the low-rate wake-up preamble can be detected, detects the narrow-band header 312, and switches to the full rate to receive the PHY frame 310. When the receiving apparatus 200 is a device using the MIMO scheme, low-rate sampling can operate only one of several receiver chains to minimize power consumption

FIG. 6 is a diagram illustrating an example of transmission / reception considering both a legacy receiving apparatus and a proposed receiving apparatus according to the proposed wakeup protocol.

The legacy receiving apparatus 600 can normally receive the existing data frame 620. However, the frame 430 including the narrow-band STF and the reduced STF of FIG. 4 may be received by the S-STF 431) is used. Therefore, the legacy receiving apparatus 600 may not normally recognize the PHY frame because the narrowband STF 421 including the detection information is sampled at a low rate.

The transmitting apparatus 100 may transmit a control frame such as the CTS-to-self 610 to the legacy receiving apparatus 600 for compatibility with the legacy receiving apparatus 600 to notify the legacy receiving apparatus 600 that the channel is used for a predetermined time.

Hereinafter, a transmission / reception method using the low-rate wake-up preamble configured as above will be described with reference to the drawings.

FIG. 7 is a flowchart illustrating a process of generating and transmitting a frame including a low-rate wake-up preamble according to an embodiment of the present invention.

Referring to FIG. 7, the transmitting apparatus 100 generates a MAC frame in step 710, and adds a PHY header to a MAC frame in step 712 to generate a PHY frame.

In step 714, the transmission apparatus 100 generates a narrow band header that is sampled at a low rate. The narrowband header is a preamble generated by extending the signal of the PHY header included in the PHY frame and reducing the bandwidth for transmitting the PHY header.

The transmitting apparatus 100 inserts the narrowband header into the PHY frame in step 716 and transmits the PHY frame in which the narrowband header is inserted in step 718. [

8 is a flowchart illustrating a process of receiving a frame including a low-rate wake-up preamble according to a proposed embodiment. Referring to FIG. 8, in step 810, the receiving apparatus 200 samples the low-rate wakeup preamble at a low rate.

In step 812, the receiving apparatus 200 determines whether a low-rate wake-up preamble is detected.

If the low-rate wake-up preamble is not detected as a result of step 812, the receiving apparatus 200 returns to step 810 and repeats the procedure of step 812 repeatedly.

If it is determined in step 812 that the low-rate wake-up preamble is detected, the receiving apparatus 200 switches the sampling operation of the receiving apparatus 200 to a full rate in step 814.

In step 816, the receiving apparatus 200 samples the packet at a full rate and receives the PHY frame.

Thereafter, the receiving apparatus 200 proceeds to step 818 and detects whether or not a full rate sampling operation is completed. Whether the full rate sampling operation has been completed can be confirmed through a more bit indicating that the next received frame exists or if the frame is not received for a predetermined time, can do.

If it is determined in step 818 that the full rate sampling operation is not completed, the receiving apparatus 200 samples the packet at the full rate in step 820 and waits for reception of the PHY frame or reception of the PHY frame.

When the full rate sampling operation is completed in step 818, the receiving apparatus 200 switches the sampling operation of the receiving apparatus to a low rate in step 820.

The above-described methods may be implemented in the form of program instructions that can be executed through various computer means and recorded on a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

Claims (20)

A physical layer frame generation unit for generating a physical layer frame by inserting a physical layer (PHY) header into a MAC layer; And
And a narrowband header inserter for inserting a narrowband header sampled at a low rate into the physical layer frame,
Wherein the bandwidth of the narrow-band header is narrower than the bandwidth of the physical layer header
Transmitting apparatus.
The method according to claim 1,
Determining whether insertion of the narrow-band header is necessary, determining whether to insert the narrow-band header, and controlling the narrow-band header inserting unit
Transmitting apparatus.
3. The method of claim 2,
Wherein,
When it is determined that the receiving apparatus is in an idle listening state sampling at a low rate,
Transmitting apparatus.
The method according to claim 1,
The narrow-
A signal of the physical layer header is extended and a low rate wakeup preamble generated by reducing the bandwidth for transmitting the physical layer header
Transmitting apparatus.
A rate control unit that samples at a low rate in an idle listening state and controls a sampling rate to sample at a full rate when receiving a physical layer frame;
A digital converter for sampling the received analog signal under the control of the rate controller at the low rate or the full rate and converting the sampled analog signal into a digital signal; And
And a preamble detecting unit for detecting a low rate wakeup preamble in the digital signal sampled at a low rate in the digital converting unit,
The bandwidth of the low rate wakeup preamble is smaller than the bandwidth of the physical layer header included in the physical layer frame
Receiving device.
6. The method of claim 5,
The low-rate wake-up preamble includes:
A signal of a physical layer header is extended, and a narrow-band header generated by reducing a bandwidth for transmitting the physical layer header
Receiving device.
6. The method of claim 5,
Wherein the rate control unit comprises:
When the preamble detection unit detects the low rate wakeup preamble, controls to sample at the full rate
Receiving device.
8. The method of claim 7,
Wherein the rate control unit comprises:
When it is detected that the sampling operation of the full rate is completed, control is performed such that sampling is performed at the low rate
Receiving device.
9. The method of claim 8,
Wherein the rate control unit comprises:
The completion of sampling operation of the full rate is detected through a more bit indicating the presence of a physical layer frame to be received next, or the completion of the full rate sampling operation is detected if a physical layer frame is not received for a predetermined time
Receiving device.
6. The method of claim 5,
And a physical layer processing unit for processing physical layer frames,
Wherein the digital converter converts the digital signal sampled at the full rate and converts the digital signal into the digital signal,
Receiving device.
Generating a physical layer frame by inserting a physical layer (PHY) header into a MAC layer; And
And inserting a narrowband header that is sampled at a low rate in the physical layer frame,
Wherein the bandwidth of the narrow-band header is narrower than the bandwidth of the physical layer header
A method for transmitting a frame comprising a low-rate wake-up preamble.
12. The method of claim 11,
Prior to inserting the narrowband header,
Determining whether insertion of the narrowband header is necessary, and determining whether to insert the narrowband header
A method for transmitting a frame comprising a low-rate wake-up preamble.
13. The method of claim 12,
Wherein the determining whether to insert the narrowband header comprises:
If it is determined that the receiving apparatus is in an idle listening state sampling at a low rate, it is determined to insert the narrowband header
A method for transmitting a frame comprising a low-rate wake-up preamble.
12. The method of claim 11,
The narrow-
A signal of the physical layer header is extended and a low rate wakeup preamble generated by reducing the bandwidth for transmitting the physical layer header
A method for transmitting a frame comprising a low-rate wake-up preamble.
12. The method of claim 11,
Further comprising sampling and transmitting at a full rate a control frame indicating that a physical layer frame in which the narrowband header is inserted is transmitted prior to transmitting the physical layer frame in which the narrowband header is inserted
A method for transmitting a frame comprising a low-rate wake-up preamble.
Sampling an analog signal received in an idle listening state at a low rate and converting the analog signal into a digital signal;
Detecting a low rate wakeup preamble in the digital signal sampled at the low rate; And
Sampling the physical layer frame of the received analog signal at full rate upon sensing the low rate wakeup preamble,
The bandwidth of the low rate wakeup preamble is smaller than the bandwidth of the physical layer header included in the physical layer frame
A method for receiving a frame comprising a low-rate wake-up preamble.
17. The method of claim 16,
The low-rate wake-up preamble includes:
A signal of a physical layer header is extended, and a narrow-band header generated by reducing a bandwidth for transmitting the physical layer header
A method for receiving a frame comprising a low-rate wake-up preamble.
17. The method of claim 16,
Sampling the received analog signal at the full rate and converting the received analog signal into a physical layer frame when detecting the low rate wakeup preamble
A method for receiving a frame comprising a low-rate wake-up preamble.
17. The method of claim 16,
And when it is detected that the sampling operation of the full rate is completed, converting the sampling rate to be sampled at the low rate
A method for receiving a frame comprising a low-rate wake-up preamble.
20. The method of claim 19,
The completion of the sampling operation of the full-
The physical layer frame is detected through a more bit indicating the presence of the next physical layer frame to be received or if the physical layer frame is not received for a predetermined time
A method for receiving a frame comprising a low-rate wake-up preamble.

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