ENABLING COEXISTENCE BETWEEN WIRELESS NETWORKS AND RADAR SYSTEMS

TECHNICAL FIELD

This invention relates generally to wireless networks and, more specifically, relates to sharing radar bands between wireless networks and radar systems.

BACKGROUND

This section is intended to provide a background or context to the invention disclosed below. The description herein may include concepts that could be pursued, but are not necessarily ones that have been previously conceived, implemented or described. Therefore, unless otherwise explicitly indicated herein, what is described in this section is not prior art to the description in this application and is not admitted to be prior art by inclusion in this section. Abbreviations that may be found in the specification and/or the drawing figures are defined below at the end of the specification but prior to the claims.

The coexistence of wireless systems (such as a Wi-Fi system) and radar seems to be forbidden by regulatory requirements, as regulatory requirements deny use of a wireless channel if radar has been detected. However, with the recent Presidential Council of Advisory for Science and Technology (PCAST) report, the military bands (S band) will be unleashed for secondary uses of communications systems (e.g., Wi-Fi and LTE as examples). Based on this report, DARPA has approved a recent project termed as Shared Spectrum Access of Radar Bands by Communications systems (SSPARC).

Military radars typically operate in the so-called S-band (2-4 GHz) and beyond with high transmission power (e.g., 150 KW) using phased array antennae. The radar signals are extremely susceptible to interference from other communications systems, leading to severe degradation in detection performance of target applications.

Meanwhile, with respect to Wi-Fi systems, channel access in Wi-Fi systems is based on contention among active STAs having UL traffic. That is, all Wi-Fi systems are contention-based TDD systems where the access point and the mobile stations all vie for use of the same channel. The traditional method of contention used in Wi-Fi systems is carrier sense multiple access-collision avoidance (CSMA-CA), where a STA needs to sense for an idle channel prior to its transmission. The interframe sensing (IFS) interval and the corresponding back-off method to reduce collisions are typical overheads of any Wi-Fi system.

If Wi-Fi and other wireless systems are to coexist with radar systems, the wireless users will be treated as secondary users and need to impart reduced interference (relative to normal operation) to the radar signals. In the absence of a coexistence mechanism, wireless devices such as STAs in a Wi-Fi system may contend for the channel and access the channel medium when the channel medium is sensed by a STA as being idle. However, during transmissions, if a radar signal appears, the ongoing transmissions will collide with the radar signal, resulting in packet loss of such STAs and other wireless devices. Since the exclusion zone of a radar signal is significant, concurrent transmissions will result in reduced system throughput. Moreover, for the example of STAs, these STAs may assume collisions with other STA transmissions and continue retransmissions with subsequent failure, since STAs are not being informed of radar operation.

In other words, in case coexistence among wireless systems such as LTE or Wi-Fi systems with radars is allowed, a problem is that there are no obvious solutions as to how to guarantee both radar operation and wireless operation in the same or adjacent channels.

SUMMARY

This section contains examples of possible implementations and is not meant to be limiting.

In an exemplary embodiment, an apparatus includes one or more processors and one or more memories including computer program code. The one or more memories and the computer program code configured, with the one or more processors, to cause the apparatus to perform at least the following: determining by a wireless access node of a wireless system whether the wireless system and a radar system are operating concurrently or will be operating concurrently within a predetermined time, wherein concurrent operation comprises both the wireless system and the radar system using at least a portion of a wireless medium; configuring, based on determining the wireless system and the radar system are operating concurrently or will be operating concurrently within the predetermined time, a frame to indicate to wireless devices using the wireless medium whether to release the wireless medium immediately or to release the wireless medium at a time in the future, and transmitting the configured frame toward the wireless devices.

Another exemplary embodiment is a method including: determining by a wireless access node of a wireless system whether the wireless system and a radar system are operating concurrently or will be operating concurrently within a predetermined time, wherein concurrent operation comprises both the wireless system and the radar system using at least a portion of a wireless medium; configuring, based on determining the wireless system and the radar system are operating concurrently or will be operating concurrently within the predetermined time, a frame to indicate to wireless devices using the wireless medium whether to release the wireless medium immediately or to release the wireless medium at a time in the future, and transmitting the configured frame toward the wireless devices.

A further exemplary embodiment is an apparatus including: means for determining by a wireless access node of a wireless system whether the wireless system and a radar system are operating concurrently or will be operating concurrently within a predetermined time, wherein concurrent operation comprises both the wireless system and the radar system using at least a portion of a wireless medium; means for configuring, based on determining the wireless system and the radar system are operating concurrently or will be operating concurrently within the predetermined time, a frame to indicate to wireless devices using the wireless medium whether to release the wireless medium immediately or to release the wireless medium at a time in the future, and means for transmitting the configured frame toward the wireless devices.

In an additional exemplary embodiment, a computer program product comprises a computer-readable storage medium bearing computer program code embodied therein for use with a computer. The computer program code comprises: code for determining by a wireless access node of a wireless system whether the wireless system and a radar system are operating concurrently or will be operating concurrently within a predetermined time, wherein concurrent operation comprises both the wireless system and the radar system using at least a portion of a wireless medium; code for configuring, based on determining the wireless system and the radar system are operating concurrently or will be operating concurrently within the predetermined time, a frame to indicate to wireless devices using the wireless medium whether to release the wireless medium immediately or to release the wireless medium at a time in the future, and code for transmitting the configured frame toward the wireless devices.

In an exemplary embodiment, an apparatus includes one or more processors and one or more memories including computer program code. The one or more memories and the computer program code configured, with the one or more processors, to cause the apparatus to perform at least the following: determining whether a wake up of a wireless device occurs before or at a time of a frame indicating a period for transmission opportunity by wireless devices in a wireless network is over; responsive to a determination the wireless device woke up at the time of the frame indicating the period for transmission opportunity by wireless devices in the wireless network is over, determining based on first information in the frame when to release a wireless medium and releasing the wireless medium based on the determining when to release the wireless medium; and responsive to a determination the wireless device woke up before the time of the frame indicating the period for transmission opportunity by wireless devices in the wireless network is over, determining based on second information in the frame when to contend for access to the wireless medium and contending to access to the wireless medium based on the determining when to contend for access to the wireless medium.

In an additional exemplary embodiment, a computer program product comprises a computer-readable storage medium bearing computer program code embodied therein for use with a computer. The computer program code comprises: code for determining whether a wake up of a wireless device occurs before or at a time of a frame indicating a period for transmission opportunity by wireless devices in a wireless network is over; code, responsive to a determination the wireless device woke up at the time of the frame indicating the period for transmission opportunity by wireless devices in the wireless network is over, for determining based on first information in the frame when to release a wireless medium and releasing the wireless medium based on the determining when to release the wireless medium; and code, responsive to a determination the wireless device woke up before the time of the frame indicating the period for transmission opportunity by wireless devices in the wireless network is over, for determining based on second information in the frame when to contend for access to the wireless medium and contending to access to the wireless medium based on the determining when to contend for access to the wireless medium.

An apparatus includes: means for determining whether a wake up of a wireless device occurs before or at a time of a frame indicating a period for transmission opportunity by wireless devices in a wireless network is over; means, responsive to a determination the wireless device woke up at the time of the frame indicating the period for transmission opportunity by wireless devices in the wireless network is over, for determining based on first information in the frame when to release a wireless medium and releasing the wireless medium based on the determining when to release the wireless medium; and means, responsive to a determination the wireless device woke up before the time of the frame indicating the period for transmission opportunity by wireless devices in the wireless network is over, for determining based on second information in the frame when to contend for access to the wireless medium and contending to access to the wireless medium based on the determining when to contend for access to the wireless medium.

An exemplary embodiment is a method, including: determining whether a wake up of a wireless device occurs before or at a time of a frame indicating a period for transmission opportunity by wireless devices in a wireless network is over; responsive to a determination the wireless device woke up at the time of the frame indicating the period for transmission opportunity by wireless devices in the wireless network is over, determining based on first information in the frame when to release a wireless medium and releasing the wireless medium based on the determining when to release the wireless medium; and responsive to a determination the wireless device woke up before the time of the frame indicating the period for transmission opportunity by wireless devices in the wireless network is over, determining based on second information in the frame when to contend for access to the wireless medium and contending to access to the wireless medium based on the determining when to contend for access to the wireless medium.

BRIEF DESCRIPTION OF THE DRAWINGS

In the attached Drawing Figures:

FIG. 1 illustrates an antenna pattern for a radar system in a polar coordinate graph;

FIG. 2A is an example of a Wi-Fi system and a radar system where a beam caused by the radar system is shown pointing in multiple directions;

FIG. 2B is a block diagram illustrating possible internal implementations of certain parts of the systems shown in FIG. 2A;

FIG. 3 shows a proposed NDP CTS frame format;

FIG. 4 is a block diagram of an exemplary logic flow diagram performed by an access point for channel access of Wi-Fi in radar bands using specific broadcast frames such as periodic NDP CTS frames, and that illustrates the operation of an exemplary method, a result of execution of computer program instructions embodied on a computer readable memory, and/or functions performed by logic implemented in hardware, in accordance with exemplary embodiments herein;

FIG. 5 is a block diagram of an exemplary logic flow diagram performed by a station for channel access of Wi-Fi in radar bands using specific broadcast frames such as periodic NDP CTS frames, and that illustrates the operation of an exemplary method, a result of execution of computer program instructions embodied on a computer readable memory, and/or functions performed by logic implemented in hardware, in accordance with exemplary embodiments herein;

FIG. 6 illustrates a scenario depicting severe interference during channel access within TxOP;

FIG. 7 illustrates a modified frame format of a CF-End frame;

FIGS. 8A and 8B show a block diagram of an exemplary logic flow diagram performed by an access point (e.g., access node) for wireless medium access of a wireless network in radar bands, and that illustrates the operation of an exemplary method, a result of execution of computer program instructions embodied on a computer readable memory, and/or functions performed by logic implemented in hardware, in accordance with exemplary embodiments herein; and

FIG. 9 is a block diagram of an exemplary logic flow diagram performed by a station for wireless medium access of a wireless network in radar bands, and that illustrates the operation of an exemplary method, a result of execution of computer program instructions embodied on a computer readable memory, and/or functions performed by logic implemented in hardware, in accordance with exemplary embodiments herein.

DETAILED DESCRIPTION OF THE DRAWINGS

The description below is provided mainly in terms of Wi-Fi systems coexisting with radar systems. However, the techniques are applicable to any wireless system that coexists with one or more radar systems.

With regard to Wi-Fi systems, in conventional systems using 802.11h, a coexistence mechanism is defined and termed as intermittent DCF for detection of radar in cochannels. Based on this method, the AP defines a fixed schedule for a quiet period, where STAs are prohibited from transmissions and are needed to sense the operating channel for presence of possible radar signals. Typically, every half-beacon interval, such a quiet period is allowed. Between two successive quiet periods, there is a high probability of radar signal occurrence within the Wi-Fi transmission range.

The ETSI and FCC had imposed rules and regulations on emission masks for other secondary devices operating in radar bands. It was required by those regulatory authorities that secondary devices need to sense for radar signals and switch from a channel upon radar detection to a different channel devoid of radar operation. However, due to the recent Presidential Memorandum and PCAST report, exclusivity of spectrum operation is no longer a viable option, thereby encouraging shared spectrum coexistence among radar and secondary communication devices.

As a broad overview, the exemplary embodiments herein provide techniques for such sharing. Exemplary embodiments herein include a coexistence mechanism of channel access for wireless systems such as Wi-Fi systems operating in the same channel(s) as that of an operating radar system. Exemplary techniques will reduce interference imposed to radar signals operating in the same bandwidth as, e.g., Wi-Fi signals. In order to provide the reduced interference, an exemplary proposal herein is that an AP broadcasts a specific broadcast frame such as a periodic NDP CTS (null data packet clear to send) frame, wherein the period is a function of a shift in beam position by an operating radar system. That is, at every change in beam position of the radar system, the AP broadcasts an NDP CTS frame. Moreover, another exemplary proposal places an additional field in the existing NDP CTS with some new definitions for implicit channel access indications using the existing Duration field in the NDP CTS frame. Similar techniques may be used for other wireless systems, although the specific broadcast frames may be different in those wireless systems.

Information is now presented regarding radar systems suitable for sharing the bandwidth with wireless systems such as Wi-Fi systems. Military radars have fixed locations and transmit with constant power spectral density at any beam position in the searching phase. The radars also possess a fixed beam spacing and fixed rotational patterns of their beams. For each beam position, there will be a fixed interference range for other coexisting communication systems. This range gradually shifts with varying beam position.

Reference is made to FIG. 1, which illustrates an antenna pattern for a radar system in a polar coordinate graph. In FIG. 1, the main lobe has a power of 0 (zero) dB. The side loges (at about a 30 degree angle) have powers of about −40 dB, meaning that the side lobes ratio is −40 dB. The rear lobe has a power of about −44 dB, meaning that the front-to-back ratio is about −44 dB.

Certain exemplary embodiments herein exploit the regular pattern of beam rotations and scanning time at every beam position of radars with electronically steered phased array antennae. Typically, such a radar antenna generates a beam at a specific azimuth angle with fixed beam spacing and beam width. After a fixed number of pulses transmitted in a beam at a fixed azimuth angle, the antenna array shifts the beam to the next pre-defined azimuth angle with fixed beam width. The entire set of beams is generated over the azimuth sector, and the entire process is repeated. Note that the sweep can be from left to right, right to left, top to bottom, or bottom to top. Other examples are possible. Based on the example provided, the following terms are defined:

Beam width: in terms of degrees of azimuth and/or elevation (where elevation is shown) in FIG. 1;

Beam spacing: difference between beam width of two adjacent beams; and

Beam position: any value from one position to many positions.

A duty cycle can indicate how long a beam is active at a particular beam position. Additionally, standoff distance S for radar is the minimum distance permitted by spectrum management processes between the nearest wireless (such as Wi-Fi) node and the nearest radar receiver or transmitter when a wireless network such as a Wi-Fi network and radar operate in the same frequency band, to prevent interference. This standoff distance is computed such that the target range is reduced by not less than five percent and the wireless (Wi-Fi in this example) network aggregate throughput is not less than 95 percent. The standoff distance defines the exclusion zone for a wireless node such as a Wi-Fi node.

Turning to FIG. 2A, FIG. 2A is an example of a wireless system (e.g., a Wi-Fi system) 250 and a radar system 210 where a beam 280 caused by the radar system points may be made to point in multiple directions 260. The beam 280 includes a main lobe 220 and the beam 280 is formed by the antenna array 215 of the radar system 210. For simplicity, only the main lobe 220 of the beam 280 is shown and the side and rear lobes are not shown. The direction 260 of the beam 280 and the main lobe 220 are the same (e.g., the side and rear lobes are ignored for this example). A first position shows the beam 280-1 and its main lobe 220-1 pointing in the direction 260-1 of 45 degrees, a second position shows the beam 280-2 and its main lobe 220-1 pointing in the direction 260-2 of zero degrees, and a third position shows the beam 280-3 and the main lobe 220-3 pointing in the direction 260-3 of 315 degrees. The 45 and 315 degree angles are the exemplary azimuth limits of the main lobe 220. It should be noted that the Wi-Fi system 250 is also called a BSS (Basic Service Set).

In FIG. 2A, the AP 230 and stations (STAs) 240-1, 240-2 should be able to communicate using Wi-Fi resources that overlap with the bandwidth used by the radar system 210, for those directions 260 where the beam 280 is pointed in directions 260 other than at the system 250 (or the directions 260 point some predetermined distance away from the Wi-Fi system 250). At some point as the main lobe 220 nears the 315 degree angle, the system 250 will no longer be able to communicate without error using the bandwidth also used by the radar system 210. Since there are 60 beam positions in the example from above, the Wi-Fi system 250 should be able to communicate using the bandwidth used by the radar system 210 for many of those positions. Reference 298 is an illustration of a standoff distance relative to the Wi-Fi system 250. This example assumes the standoff distance 298 corresponds to an azimuth for the beam 280 of 325 degrees. It is assumed the Wi-Fi system 250 can determine this standoff distance 298. This standoff distance 298 still provides a lot of the rotation of the beam 280 in which the Wi-Fi system 250 may communicate. For instance, if the Wi-Fi system 250 can communicate when the beam is at X of Y positions, then the Wi-Fi system 250 should be able to communicate (at least) for (X/Y)*Z ms of each Z*Y ms.

Turning to FIG. 2B, a block diagram is shown illustrating possible internal implementations of certain parts of the system shown in FIG. 2A. In FIG. 2B, two stations (e.g., mobile devices) 240-1 and 240-2 may be in wireless communication with the AP (e.g., a wireless access node providing access to the system 250) 230 via wireless links 416-1 and 416-2, respectively. The two STAs 240-1 and 240-2 are assumed to be similar and only possible internal implementation of the STA 240-1 is described.

The STA 240-1 includes one or more processors 450, one or more memories 455, one or more transceivers 460, and one or more network (N/W) interfaces (I/Fs) 465, interconnected through one or more buses 457. The STA 240-1 includes one or more antennas 458. The one or more memories 455 include computer program code 453. Each of one or more transceivers 460 includes one or more transmitters (Tx) 461 and one or more receivers (Rx) 462. The STA 240-1 includes a Wi-Fi controller 430, which causes the STA 240-1 to perform at least the techniques presented herein. In an exemplary embodiment, the Wi-Fi controller 430 may be implemented (in part or wholly) as computer program code 453, such that the one or more memories 455 and the computer program code 453 are configured, with the one or more processors 450, to cause the STA 240-1 to perform techniques presented herein. In another exemplary embodiment, the Wi-Fi controller 430 may be (in part or wholly) implemented as hardware logic, such as being implemented in an integrated circuit, programmable logic device, or the like. The hardware logic may be part of the one or more processors 450 or separate circuitry. The one or more buses 457 may be any type of connection, such as traces on a motherboard, lines on a semiconductor, fiber optics, wireless connections, and the like.

The AP 230 includes one or more processors 420, one or more memories 425, one or more network interfaces (N/W I/F(s)) 410, and one or more transceivers 405 (each comprising a transmitter, Tx, 406 and a receiver, Rx, 407) interconnected through one or more buses 459. The one or more transceivers are connected to the one more antennas 401. The one or more buses 459 may be any type of connection, such as traces on a motherboard, lines on a semiconductor, fiber optics, wireless connections, and the like. The one or more memories 425 include computer program code 432. The AP 230 includes a Wi-Fi controller 415, which causes the AP 230 to perform at least the techniques presented herein. In an exemplary embodiment, the Wi-Fi controller 415 may be implemented (in part or wholly) as computer program code 432, such that the one or more memories 425 and the computer program code 432 are configured, with the one or more processors 420, to cause the AP 230 to perform techniques presented herein. In another exemplary embodiment, the Wi-Fi controller 415 may be (in part or wholly) implemented as hardware logic, such as being implemented in an integrated circuit, programmable logic device, or the like. The hardware logic may be part of the one or more processors 420 or separate circuitry.

The one or more network interfaces 465, 410 communicate over different types of networks, such as USB (Universal Serial Bus), Bluetooth, or wired LAN as examples. In an example, the AP 230 uses the one or more network interfaces 410 to access a network (such as the Internet) using link 428, where the network node 437 resides on the network. The network node 437 may include a database 438 in certain exemplary embodiments, where the database is able to be written to by the radar system 210 (or by an entity able to determine information about the radar transmissions from the radar system 210). The database 438 is described in more detail below.

The computer readable memories 455, 425 may be of any type suitable to the local technical environment and may be implemented using any suitable data storage technology, such as semiconductor based memory devices, flash memory, magnetic memory devices and systems, optical memory devices and systems, fixed memory and removable memory. The processors 450, 420 may be of any type suitable to the local technical environment, and may include one or more of general purpose computers, special purpose computers, general or special purpose integrated circuits, microprocessors, digital signal processors (DSPs) and processors based on a multi-core processor architecture, as non-limiting examples.

In order to provide communication and corresponding sharing by the Wi-Fi system 250 of the bandwidth used by the radar system 210, an exemplary proposal herein advertises in one or more specific broadcast frames whether the Wi-Fi channel is or is not available for contention-based access. A specific example defines a new field in an NDP CTS frame 300 termed as the “Next NDP CTS Crossing” field 310. See FIG. 3, which shows a proposed NDP CTS frame 300 format. In this example, the following fields 310 are shown: The NDP MAC Frame Type 310-1 (3 bits); Broadcast/Unicast 310-2 (1 bit); RA/PBSSID (Receiver Address/Partial Basic Service Set IDentifier) 310-3 (9 bits); Duration 310-4 (10 bits); Early Selector Indicator 310-5 (1 bit); and Next NDP CTS Crossing 310-6 (1 bit). The Duration field 310-4 is currently used by receiving STAs to set the NAV for the amount of time indicated in the Duration field. In conventional systems, the Duration value of 0 (zero) has no specific meaning.

In an exemplary embodiment, the field 310-6 implies whether a STA 240 which gained access to a channel is allowed to transmit data even at the time of the next scheduled NDP CTS frame. If the bit in the field 310-6 is set to 1 (one) (for instance), the STA is allowed to transmit at the time of the next scheduled NDP CTS and the AP 230 waits for the end of the data transmission in order to broadcast the next NDP CTS frame 300.

In an exemplary embodiment, the AP 230 sets this bit in field 310-6 to 0 (zero) (for instance) when the AP 230 determines that the main lobe 220 is approaching the BSS (e.g., the system 250). In order to restrict transmissions when the BSS is aligned with the main lobe 220 at the next scheduled NDP CTS frame transmission time, a STA 240 gaining access to the channel via contention, following the current NDP CTS frame transmission, may be prohibited from having its transmission cross the time of the next scheduled NDP CTS frame.

Moreover, implicit indication of channel access may be controlled by the AP 230 (e.g., alternatively to or in addition to the Next NDP CTS Crossing field 310) using the Duration field 310-4. A zero value in this field 310-4 indicates to the STAs 240 that the STAs 240 may contend for and access the channel until the next scheduled NDP CTS frame 300. However, a non-zero value in this field 310-4 indicates that STAs shall not contend for the channel for the indicated duration (e.g., in milliseconds). This access prohibition is due to the main lobe alignment with the BSS and no operation shall be allowed for the duration of main lobe alignment with the BSS.

In another exemplary embodiment, it is proposed that the AP 230 periodically broadcasts an NDP CTS frame 300 at every change in beam position of the radar signal. This NDP CTS frame 300 transmission is periodic in nature depending the duration after which a radar system changes its beam position. The STAs 240 after receiving the NDP CTS frame may either contend for the channel and gain access to the medium (e.g., zero value in Duration field) or set a NAV for the indicated duration in the Duration field and freeze their back-off counter if within contention. As is known, in carrier sense-based channel access, a STA senses for idle medium prior to transmission. If the medium is idle, the STA initiates back-off and selects a random number between 0 and 31. When the back-off counter decrements to zero, the STA gains access to the channel. However, during the back-off, if the STA senses the medium to be busy, the STA freezes its counter, i.e., does not decrement its counter from the present value and sets the NAV equivalent to the duration specified in the packet of current transmission for which the STA senses the medium to be busy. The NAV, therefore, is an indicator for a station on how long the STA must defer from accessing the channel.

The AP 230 may obtain the information of beam position from a database (e.g., database 438, see FIG. 2B) that keeps track of radar operation in a wide region. The database 438 in the network node 437 includes a number (typically several or many) of entries 470, of which one exemplary entry 470-1 is shown. In this example, the entry 470-1 includes the following: beam width (as defined above); beam spacing (as defined above), a number of beam positions (where a beam position is defined above); a duty cycle (e.g., a time period where a radar beam is active at one of the beam positions); a location (e.g., a latitude-longitude location of the radar system 210); and beam properties (e.g., which describe details of the beam). It is expected that the AP synchronizes with the radar beam using the database that provides exact beam position of radar signal. Typical range of a radar beam might be 20 km, directions are typically in azimuth and elevation. Various radars may operate with different values and the items in the entry 470-1 are merely exemplary.

The AP 230 may access the database frequently for timely information to the associated STAs 240 to be broadcasted over the NDP CTS frame 300. The AP 230 may provide the received information about radar operation in Beacon and Probe Response frames. The STAs 240 decode the Beacon or Probe Response frames in order to retrieve the information as well as decode the NDP CTS frame 300 for channel access. Broadly, a STA waking up shall not contend until the STA receives an NDP CTS frame. On receiving an NDP CTS frame, the BSS contends for the channel by initiating back-off. If the Duration field in the NDP CTS frame is set to 0 (zero, as an example), the STAs are not allowed to contend for the channel, thereby prohibiting channel access when the main lobe is aligned with the Wi-Fi BSS. Finally, if a STA 240 wakes up after a scheduled NDP CTS frame 300, the STA 240 shall not transmit a short or long frame until the STA 240 receives the next scheduled NDP CTS frame 240.

Referring now to FIG. 4, this figure is a block diagram of an exemplary logic flow diagram performed by an access point for channel access of Wi-Fi in radar bands using specific broadcast frames such as periodic NDP CTS frames. FIG. 4 illustrates the operation of an exemplary method, a result of execution of computer program instructions embodied on a computer readable memory, and/or functions performed by logic implemented in hardware, in accordance with exemplary embodiments herein. The blocks in FIG. 4 may also be considered to be interconnected means for performing the functions in the blocks. The blocks in FIG. 4 are assumed to be performed by the AP 230, e.g., under control (at least in part) by the Wi-Fi controller 415.

In block 505, the AP 230 performs the operation of determining information about a pattern of a radar beam. The radar beam uses a bandwidth. As described above, the information may be determined by accessing the database 438 and determining the information in the entries 470. Other options are also possible, such as radar systems 210 (or other entity) could send their information directly to the AP 230. In block 510, the AP 230 performs the operation of transmitting at least some of the information about the pattern of the radar beam in beacon and probe response frames. This information could include information about the periodicity, location of the radar, transmit power, nulls of radar beam, as examples. In block 515, the AP 230 performs the operation of determining based on the information about the pattern whether a channel using at least a portion of the bandwidth is or is not available for access. This determining may be performed based on information from the database 438. For instance, knowing the location of the radar system 210, the length of the beam 280, the orientation of the beam 280, the location of the AP 230, and the like, the AP 230 can use geometry (for instance) to determine when the radar system 210 will affect communication with STAs. For instance, the AP 230 may use this information to determine the standoff distance 298. Furthermore, the AP 230 may also sense for radar operation in addition to collecting information from the database 438 and use the sensing for further refinement of determining when the radar system 210 will affect communication with STAs. The access can be contention-based access 515, which is a primary exemplary embodiment herein. However, the access can be contention-free access 517, such as that performed by LTE, which involves scheduling by a base station (e.g., eNB) of communications by a mobile device (e.g., user equipment).

In block 525, the AP 230 performs the operation of transmitting one or more specific broadcast frames configured to advertise whether the channel is or is not available for access. In contention-based access 516, the advertisement would be an actual “advertisement” in Wi-Fi parlance. In contention-free access 517, the advertisement could be a message or a part thereof sent by a base station to a mobile device.

Block 520 is an example of block 515, and block 545 is an example of block 525. In block 520, the AP 230 performs the operation of determining whether the radar beam is or is not within a predetermined distance to the access point. In block 545, the AP 230 advertises by including a value indicating whether the radar beam is or is not within a predetermined distance to the wireless access node 230 (e.g., access point).

Block 530 is an example of block 525. In block 530, the AP 230 performs the operation of periodically transmitting the one or more specific broadcast frames. The period of transmission is based on rotation (e.g., change in position in azimuth or elevation angle of the radar beam) of the radar beam, as described above. Block 535 is performed based on block 530. In block 535, for contention-based access 516, the AP 230 performs the operation of advertising by including a value such as the Next NDP CTS Crossing value (e.g., in the field 310-6). As stated above, this value indicates whether a mobile device (e.g., STA 240) may perform one or more transmissions, if contention for the channel is won by the mobile device, that will cross a time at which a subsequent specific broadcast frame is scheduled to be transmitted based on the period or cannot perform the one or more transmissions that will cross the time at which the subsequent specific broadcast frame is scheduled to be transmitted. That is, e.g., if the Next NDP CTS Crossing value is one value, the STA 240 should stop transmitting (assuming the STA 240 won contention and is or will be transmitting) before the next NDP CTS frame 300 is scheduled to be transmitted by the AP, wherein the scheduling is based on the period. That is, e.g., if the Next NDP CTS Crossing value is a second value, the STA 240 may continue transmitting (assuming the STA 240 won contention and is transmitting) after the time the next NDP CTS frame 300 is scheduled to be transmitted by the AP. Regarding contention-free access 517, a wireless access device 230 (such as an LTE base station) could provide a value indicating whether a mobile device (e.g., a user equipment) may perform one or more transmissions, if the mobile device is scheduled to access the channel, that will cross a time at which a subsequent specific broadcast frame is scheduled to be transmitted based on the period or cannot perform the one or more transmissions that will cross the time at which the subsequent specific broadcast frame is scheduled to be transmitted.

In block 540, for contention-based access 516, the AP 230 performs the operation of advertising by including the Duration value (in Duration field 310-4 of the NDP CTS frame 300). As described above, the Duration value may be one of a first value indicating a mobile device such as STA 240 can contend for the channel or a second value indicating how long the mobile device should defer from accessing the channel. In an exemplary embodiment, the second value therefore indicates a NAV that should be set by the mobile device. For contention-free access 517, the wireless access node 230 could provide a value that may be one of a first value indicating a mobile device can access the channel or a second value indicating how long the mobile device should defer from accessing the channel. It should be noted that block 540 could also be combined with other blocks, such as blocks 530 and 535.

Turning to FIG. 5, this figure is a block diagram of an exemplary logic flow diagram performed by a station for channel access of Wi-Fi in radar bands using specific broadcast frames such as periodic NDP CTS frames. Further, FIG. 5 illustrates the operation of an exemplary method, a result of execution of computer program instructions embodied on a computer readable memory, and/or functions performed by logic implemented in hardware, in accordance with exemplary embodiments herein. The blocks in FIG. 5 may also be considered to be interconnected means for performing the functions in the blocks. The blocks in FIG. 5 are assumed to be performed by the STA 240, e.g., under control (at least in part) by the Wi-Fi controller 430.

In block 605, the STA 240 performs the operation of receiving at least some of the information about the pattern of the radar beam in beacon and probe response frames. This information could include information about the periodicity, location of the radar, transmit power, nulls of radar beam, as examples. The pattern of the radar beam 280 allows the STA 240, for instance, to know when the specific broadcast frames should be received and when the STA can contend for a channel or access a channel. In block 610, the STA 240 performs the operation of receiving one or more specific broadcast frames configured to advertise whether a channel is or is not available for access, which can be a contention-based access 516 or a contention-free access 517. The channel uses at least a portion of bandwidth used by a radar beam. In block 645, the STA 240 performs the operation of, in response to determining the one or more specific broadcast frames advertise that the channel is available for access (e.g., contention), access (e.g., or contending for) the channel. In block 250, the STA 240 performs the operation of, in response to determining the one or more specific broadcast frames advertise that the channel is not available for access (e.g., contention), not accessing (e.g., not contending for) the channel.

Block 615 is an example of block 610. In block 615, the STA 240 performs the operation of periodically receiving the one or more specific broadcast frames, wherein a period of reception is based on rotation (e.g., change in position in azimuth or elevation angle of the radar beam) of the radar beam. Blocks 620, 625, and 628 may be performed based on block 615. In block 620, the STA 240 performs the operation of, in response to the mobile device (e.g., STA 240) waking up after a previous specific broadcast frame, not transmitting a short or a long frame until a next scheduled specific broadcast frame is received. That is, in an exemplary embodiment, the STA 240 wakes up after a previous NDP CTS frame 300. Thus, the STA 240 wakes up between transmissions of the NDP CTS frame 300. The STA 240 therefore does transmit a short or a long frame until a next scheduled specific broadcast frame (e.g., NDP CTS frame 300) is received. In block 625, the advertising occurs by including a value such as a Next NDP CTS Crossing value (in field 310-6). As described above, this value indicates for contention-based access 516 whether the mobile device may perform one or more transmissions, if contention for the channel is won by the mobile device, that will cross a time at which a subsequent specific broadcast frame is scheduled to be transmitted based on the period or cannot perform the one or more transmissions that will cross the time at which the subsequent specific broadcast frame is scheduled to be transmitted. For contention-free access 517, the value may indicate whether the mobile device may perform one or more transmissions, if the mobile device is scheduled to access the channel, that will cross a time at which a subsequent specific broadcast frame is scheduled to be transmitted based on the period or cannot perform the one or more transmissions that will cross the time at which the subsequent specific broadcast frame is scheduled to be transmitted.

In block 628, the STA 240 performs the operation of, if the STA wakes up, the STA shall wait for the next scheduled broadcast frame transmission by the AP and received by the STA before channel access by the STA. If a specific broadcast frame is not transmitted by the AP and received by the STA at the scheduled time, the STA needs to wait for a subsequent specific broadcast frame (e.g., in a next scheduled time as defined by the period) prior to channel access by the STA. The scheduled time is based on the period, as the STA has determined the AP should transmit and the STA should receive the specific broadcast frames based on the period.

In block 630, the advertising occurs by including a value such as the Duration value for a contention-based access 516. As described above, the Duration value (e.g., in the Duration field 310-4 of the NDP CTS frame 300) is one of a first value indicating a mobile device can contend for the channel or a second value indicating how long the mobile device should defer from accessing the channel. The second value could therefore indicate that the NAV should be set by the mobile device. The STA would therefore contend for the bandwidth or set the NAV and act accordingly. For contention-free access 517, the value may be one of a first value indicating a mobile device can access the channel or a second value indicating how long the mobile device should defer from accessing the channel. It is further noted that block 630 may also be performed with blocks 615 and 625 (and 620).

In block 640, the advertising occurs by including a value indicating whether the radar beam is or is not within a predetermined distance to an access point.

As indicated above, blocks 645 and 650 would be selected accordingly for blocks 630 and 640. For instance, block 645 would be performed in response to the first value, indicating the mobile device can contend for the bandwidth, being in the Duration value (block 630) or in response to a value indicating the radar beam is not within the predetermined distance to the access point (block 640). Similarly, block 650 would be performed in response to the second value, indicating a NAV should be set by the mobile device, being in the Duration value (block 630) or in response to a value indicating the radar beam is within the predetermined distance to the access point (block 640).

Although the description above is primarily directed to Wi-Fi, the techniques may be used for other wireless systems. For instance, the examples may be used for LTE systems as described in reference above to the contention-free accesses 517. Transmission and reception herein may be performed through known techniques, such as those described by a number of 802.11 standards or LTE standards.

The description above relates, e.g., to enabling coexistence between wireless networks and radar systems. However, there are some additional considerations that may need to be addressed. As described above, coexistence of Wi-Fi and radar seems to be forbidden by regulatory requirements. However, with the recent Presidential Council of Advisory for Science and Technology (PCAST) report, the military bands (S band) will be unleashed for secondary uses of communications systems (e.g., Wi-Fi and LTE). Based on this report, DARPA has approved a recent project termed as Shared Spectrum Access of Radar Bands by Communications systems (SSPARC).

Furthermore, an enhanced distributed contention access (EDCA)-based mechanism was proposed in IEEE 802.11e for differentiated QoS users. See IEEE P802.11a/D1.0, October 2013, Draft Standard for Information technology—Telecommunications and information exchange between systems Local and metropolitan area networks—Specific requirements, Part 11: Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications, Amendment 6: Sub 1 GHz License Exempt Operation, in sub-clause 9.20.2.2., entitled “EDCA TxOPs”. The mechanism includes two parameters, AIFSN(AC) and TxOP(AC), as a function of access category (AC). Based upon the AC, each STA 240 senses the medium for idleness for AIFSN period prior to back-off. Higher priority users use smaller values of AIFSN (AC) than lower priority users. Back-off is identical as in conventional WLAN. When the back-off counter goes to zero, the STA gains a guaranteed channel access with transmission opportunity (TxOP).

An exemplary embodiment above proposed a periodic NDP CTS frame transmission. In an exemplary embodiment, in between two scheduled NDP CTS, a STA may typically gain a (transmission opportunity) TxOP for the entire duration. As defined in the IEEE 802.11 Standard (see IEEE P802.11a/D1.0, October 2013, referenced above), STAs on completing packet transmissions within TxOP may transmit a CF-End frame to the AP. In response, the AP 230 transmits another CF-End frame to acknowledge the sent CF-End frame and to inform all other STAs 240 about the termination of the TxOP. Also, as defined in IEEE 802.11 Standard (see IEEE P802.11a/D1.0, October 2013, referenced above), a STA that receives a CF-End frame shall reset its NAV and start contending for the channel immediately.

However, with the coexistence of Wi-Fi and radar systems as depicted in FIG. 6, the transmission of a CF-End frame may give rise to a problem. This may happen when a radar beam stays on a specific beam position for scanning and then detects a target at that location. If this situation occurs while the BSS overlaps with the main lobe of the radar beam, the entire BSS may be prohibited from channel access. In such a scenario, a CF-End frame may need to be modified to indicate prohibition to the entire BSS instead of the current protocol of enabling other STAs to gain access of the medium.

More specifically, it was asserted above that NDP CTS frames are transmitted periodically to inform stations of the beam position of radars. This scenario of initiation of a TxOP is after the transmission of an NDP CTS frame, when the AP 230 was conversant of the mode change from a searching mode to a tracking mode by the radar. In case of a tracking mode, the beam position might not change and such a tracking mode can be a random event based on the appearance of a target of interest T 1640 for the radar. The AP 230 may be not conversant of this mode change due to latency issues of information exchange and sharing between radar and AP. In this case, the STAs may initiate a TxOP (illustrated at 1607), assuming the prior NDP CTS indicates beam position change that is not incident on the BSS.

For instance, in FIG. 6, assume that the main lobe 220 is moving in the direction indicated by reference 1630. STA 1 has a TxOP after the Beacon frame 1605-1 and sends a CF-End frame. An exemplary typical scenario is that the main lobe 220 is moving from azimuth 1620-1 toward the coverage area 1650 formed by the AP 230 and toward azimuth 1620-2 such that there should be no contention allowed for STAs 240 in time period 1610, and the AP 230 can indicate such via the second (2^nd) CF-End frame. However, the radar finds a target, T, 1640 and in a tracking mode stays at azimuth 1620-1. This means that there may be contention allowed in time period 1610, prior to the second Beacon frame 1605-2. The AP 230 could modify the second CF-End frame to allow contention, e.g., between STAs 2 and 3.

Exemplary embodiments herein solve the problem posed above with modifications in the CF-End frame indication and also protocol changes in medium access due to this coexistence. Additionally, an exemplary improved channel access mechanism is disclosed using EDCA for Wi-Fi systems operating in the same channel as that of an operating radar for reduced interference from the latter.

More particularly the following exemplary and non-limiting concepts are introduced in exemplary embodiments herein.

1. Within the CF-End frame, the Duration field is redefined with respect to the next scheduled NDP CTS frame. Furthermore, it is proposed to include a one bit indication termed as “Channel Release” in NDP CTS to indicate to the STAs that, on receipt of such an NDP CTS frame, none of the STAs are allowed to contend for the rest of the TxOP duration. Alternatively, another proposal is to use a new “quiet” frame with similar information fields as in a CF End frame that an AP may broadcast in case the AP detects a radar mode change.

2. Another exemplary proposal is a set of rules for STAs that either wake up before or at the time of a CF-End frame transmission.

3. An additional exemplary proposal is to define a set of rules for STAs that wake up after the CF-End frame transmission.

These examples are described in more detail below. An introductory description of radar operation with respect to the exemplary embodiments is now described.

In case of search and track radars, e.g., TPQ-37, a radar transmits a predefined set of pulses to indicate mode switch, i.e., from search to track or from track to search mode. These set of pulses have a pre-defined duty cycle and are different from the set of pulses with characteristic duty cycle used for searching and tracking. The APs 230 operating co-channel will detect these predefined set of pulses and understand a mode switch operation at the radar. During the mode switch, the STAs and the AP may be in between an NDP CTS frame interval. Hence, the AP sends either a CF-End frame or a new “quiet” frame to transmit this mode change information to STAs to prevent STAs from further transmissions and therefore quiet the BSS.

Now that an introductory description of radar operation has been described, concerning the scenario when radar and Wi-Fi operate concurrently within TxOP, the following are suggested. It is proposed to modify the existing CF-End frame 700 as depicted in FIG. 7. The fields in CF-End frame 700 are described in, e.g., IEEE P802.11-REVmcTM/D1.6, September 2013, IEEE P802.11-REVmcTM/D1.6, September 2013, Draft Standard for Information technology—Telecommunications and information exchange between systems, Local and metropolitan area networks—Specific requirements, Part 11: Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications. A MAC header includes the “Frame Control” field 705, the “Duration” field 720, the “RA” field, and the “BSSID(TA)” field. In order to alleviate the problem of STAs still contending when the BSS is aligned with the main lobe 220 of the radar signal, it is proposed to replace the “More Fragments” subfield, which is a subfield of the “Frame Control” field 705, with a “Release Channel” subfield 710. The More Fragments subfield is 1 (one) bit in length and is set to 1 (one) in all Data or Management frames that have another fragment of the current MSDU or current MMPDU to follow. The More Fragments subfield is set to 0 (zero) in all other frames. In the example of FIG. 7, the “Release Channel” subfield takes the place of the “More Fragments” subfield. The “Release Channel” subfield 710 may be interpreted as follows:

(i) If the “Release Channel” subfield 710 is set to 0 (zero), the “Duration” field is not indicated in the MAC frame header; STAs behave as defined in a current 802.11 Standard, i.e., reset their NAV and contend for the channel immediately.

(ii) If the “Release Channel” subfield 710 is set to 1 (one) and the “Duration” field 720 is set to 0 (zero), this combination implies that STAs 240 need to release the channel immediately; and

(iii) If the “Release Channel” subfield is set to 1 (one) and the “Duration” field 720 is set to a non-zero value, this combination implies that STAs need to release the channel at a time indicated in the Duration field. The value of the Duration field could be set, e.g., to tens of milliseconds. The STAs perform virtual carrier sensing using NAV (Network Allocation Vector). On decoding the Duration field, the NAV counter is set to the value indicated in the Duration field. When the NAV counter time goes down to 0 (zero), the STAs start contending for the channel

Moreover, as depicted in FIG. 3, the Duration field in the NDP CTS frame 300 indicates a value corresponding to the remaining time from the transmission of CF-End frame to the next scheduled NDP CTS frame. The Duration field 720 is similar but in the CF-End frame 700.

During the TxOP time (e.g., 1607 in FIG. 6), the AP 230 still monitors the radar beam position from the radar database. If the AP detects that the main lobe is still aligned with the BSS, it may transmit a CF-End frame in response to a frame transmitted by a STA within TxOP, instead of an ACK frame.

STAs (with current TxOP and others with NAV set) on receipt of the CF-End frame, will decode the “Frame Control” field 705 with the corresponding “Release Channel” subfield 710. As opposed to the current behavior of STAs, where STAs reset their NAV and contend for the channel, with the “Release Channel” bit set to 1 (one), STAs set their NAV for a duration specified in the “Duration” field 720 of the CF-End frame 700.

Concerning the scenario when the radar main beam 220 is not aligned with Wi-Fi BSS and the STAs wake up before or at CF-End transmission, the following examples are presented. In this scenario, in case that the AP detects no interference from the radar operation, the AP 230 may allow the STA 240 which gained the TxOP to complete its transmissions. Once completed and the STA sends a CF-End frame, the AP computes the remaining time to the next scheduled NDP CTS frame transmission. As is known, the IEEE 802.11 family of standards describe the DCF protocol, which controls access to the physical medium. A station must sense the status of the wireless medium before transmitting. If the station finds that the wireless medium is continuously idle for DCF Interframe Space (DIFS) period, the station is then permitted to transmit a frame. If the wireless medium is found busy during the DIFS interval, the station should defer its transmission. The AP may use the following conditions in setting the “Duration field” 720 within the CF-End frame 700:

1) Remaining time to NDP CTS frame<DIFS period: This condition means the “Duration” field 720 is set to the time to next NDP CTS frame transmission; or

2) Remaining time to NDP CTS frame>DIFS period+N*(Slot duration): This condition means the “Duration” field 720 is set to 0 (zero). The value of N can be from 1 to [(Time to next NDP CTS/Slot Duration]. It should be noted that duration between the end of DIFS and 1*(Slot Duration) is not a meaningful time for packet transmission or for channel contention.

It is noted “Release Channel” subfield 710 is set, in an exemplary embodiment, to 1 (one) in both the cases. In case the “Duration” field 720 is set to 0 (zero), STAs reset their NAV and contend for the channel immediately. The STA with the current TxOP is not allowed to contend for the channel at this point. The AP may set the value of N slots in order to allow STAs to not only perform DIFS, but also enter back-off.

Concerning the scenario when the radar main beam 220 is not aligned with the Wi-Fi BSS and the STAs wake up after the CF-End transmission, if the STAs wake up after the CF-End frame was transmitted by the AP, the STAs shall wait for the next scheduled NDP CTS frame prior to any frame transmission.

Turning to FIGS. 8A and 8B, these figures show a block diagram of an exemplary logic flow diagram performed by an access point (e.g., access node) for wireless medium access of a wireless network in radar bands. This figure also illustrates the operation of an exemplary method, a result of execution of computer program instructions embodied on a computer readable memory, and/or functions performed by logic implemented in hardware, in accordance with exemplary embodiments herein. The blocks in this figure may be considered to be interconnected means for performing the functions of the blocks. FIGS. 8A and 8B are assumed to be performed by a wireless access node such as an AP 230, e.g., under control of a Wi-Fi controller 415.

It is noted that FIGS. 8A and 8B (and FIG. 9)—are directed to a scenario where the radar system 210 goes into tracking mode and therefore no longer is in search mode. In search mode, as described above, the radar system 210 produces a periodic signal that also follows a (e.g., rotating) pattern (e.g., in terms of azimuth progression) as described above. In FIGS. 8A and 8B (and FIG. 9), the radar system 210 is no longer operating in search mode and is instead operating in tracking mode, where the radar beam can be localized, e.g., to a certain azimuth.

In block 805, the AP 230 determines whether the wireless system (e.g., wireless system 250) and radar (e.g., system 210) are operating concurrently or will be operating concurrently within a predetermined time period. In order to make this determination, the AP 230 may (block 810) access a radar database 438 to determine whether concurrent operation is or will be occurring. The radar system 210 may update the database 438 to indicate that the radar system 210 has entered tracking mode, e.g., and may include other relevant information, such as at what azimuth(s) the tracking is occurring. Using this information, the AP 230 can determine whether the wireless system 250 and the radar system 210 is operating concurrently or will be operating concurrently within some predetermined time period. Alternatively or additionally, in block 812, the AP 230 may determine via a communication whether concurrent operation is or will be occurring. For instance, the radar system may communicate with the wireless system, e.g., via a network communication, that a switch has been made to the tracking mode. Another example is that the radar system could update an intermediary node, such as network node 437, which would then communicate with the AP 230 to inform the AP 230 of the switch in mode to the tracking mode of the radar system. Alternatively or additionally, the AP 230 may (block 815) measure the wireless medium to determine whether concurrent operation is or will be occurring. For instance, based on the typical pattern of the radar system 210 when in search mode, the AP 210 could have previously determined data indicating power of the radar beam is to be decreasing (e.g., or increasing) based on, e.g., current time in terms of a sweep of the radar beam through azimuth locations. If the AP 230, however, determines the current power of the radar beam does not fit the previously determined data, e.g., is increasing or staying the same instead of decreasing, the AP 230 could determine the wireless network 250 and the radar system 210 are operating concurrently (or will be operating concurrently within a predetermined time period). Furthermore, as stated above, in case of search and track radars, e.g., TPQ-37, a radar transmits a predefined set of pulses to indicate mode switch, i.e., from search to track or from track to search mode. These set of pulses have a pre-defined duty cycle and are different from the set of pulses with characteristic duty cycle used for searching and tracking. The APs 230 operating co-channel will detect these predefined set of pulses and understand a mode switch operation at the radar. This may also occur in block 815.

If the AP 230 determines the wireless system 250 and the radar system 210 are or will be operating concurrently (block 820=Are or will be operating concurrently), the flow proceeds to block 825. In block 825, the AP 230 computes a time to release the wireless medium (e.g., a channel). If the AP 230 computes the time to release the wireless medium as being immediately (that is, if the wireless system 250 and the radar system 210 are operating concurrently), in block 830 the AP configures a CF-End frame 700 to indicate to stations to immediately release the wireless medium. This may be done by, e.g., the AP 230 setting the Release Channel subfield 710 to a one and the Duration field 720 to a zero.

By contrast, if the AP computes the time to release the wireless medium as being in the future (some finite, predetermined, time after CF-End frame transmission such that the wireless system 250 and the radar system 210 will be operating concurrently), in block 835 the AP 230 configures the CF-End frame 700 to indicate to stations the finite time after CF-End frame transmission. The predetermined time could be, e.g., in the range of tens of milliseconds. The configuring could be performed by the AP 230 setting the Release Channel subfield 710 to a one and the Duration field 720 to a non-zero value indicating the time at which the STAs should release the wireless medium. In block 840, the AP 230 sends the configured CF-End frame 700, e.g., in response to a frame transmitted by a STA within the TxOP. The flow proceeds to block 805.

In response to a determination by the AP 230 that the wireless system 250 and the radar system 210 are not (e.g., or will not within some predetermined time period be) operating concurrently (block 820=Not operating concurrently or will not be operating concurrently), the flow proceeds to block 850. In block 850, the AP 230 determines whether a CF-End frame 700 has been received from a station. If not (block 855=No), flow proceeds to block 850, where the AP 230 waits for the CF-End frame 700.

If the CF-End frame 700 has been received (block 855=Yes), the AP computes (in block 860) the remaining time to a next scheduled NDP CTS frame (e.g., or Beacon frame). Null Data Packet Clear to Send (NDP CTS) was introduced in IEEE 802.11ah as a short packet in order to allow all STAs to contend simultaneously and also quiet the overlapping BSS STAs. A Beacon frame is one of a number of management frames in IEEE 802.11 based WLANs. A Beacon frame contains information about the network. Beacon frames are transmitted periodically to announce the presence of a Wireless LAN. Basically, both NDP CTS and Beacon frames announce an ability for the STAs to contend for the wireless medium. If the NDP CTS frame<DIFS period, the AP 230 performs block 870 and AP configures a CF-End frame 700 to indicate to stations the stations can immediately contend for the wireless medium. For instance, the Duration field 720 may be set to zero. The Release Channel subfield 710 is set to one. If the NDP CTS frame>DIFS period+N*(Slot duration), then block 865 is performed. In block 865, the AP 230 AP configures the CF-End frame to indicate to stations a duration to the next NDP CTS frame. For instance, the Duration field 720 may be set to the duration to the next NDP CTS frame. The Release Channel subfield 710 is set to one. In block 875, the AP transmits the configured CF-End frame 700. The flow proceeds to block 805.

Referring to FIG. 9, a block diagram is shown of an exemplary logic flow diagram performed by a station for wireless medium access of a wireless network in radar bands. FIG. 9 further illustrates the operation of an exemplary method, a result of execution of computer program instructions embodied on a computer readable memory, and/or functions performed by logic implemented in hardware, in accordance with exemplary embodiments herein. The blocks in this figure may be considered to be interconnected means for performing the functions of the blocks. The blocks in FIG. 9 may be performed by a mobile device, such as a STA 240, e.g., under control of a Wi-Fi controller 430.

In block 905, the STA 240 determines whether wake up occurs before, at the time of, or after CF-End transmission, e.g., the “second” CF-End transmission sent by the AP in FIG. 6. If after the CF-End transmission (block 910=After), in block 912, the STA 240 waits for the next scheduled NDP CTS frame prior to any frame transmission. If at the time of (block 910=At time of), in block 915, the STA 240 decodes the Release Channel subfield 710 of Frame Control field 705 of the CF-End frame 700. If the Release Channel subfield 710 has a first value (e.g., zero) (block 825=First value), the STA 240 in block 935 resets the NAV and contends for wireless medium access. If the Release Channel subfield 710 has a second value (e.g., one) (block 825=Second value), the STA 240 in block 940 decodes the Duration field 720. If the Duration field 720 is a zero value (block 945=Zero value), in block 950 the STA 240 releases the wireless medium immediately. If the Duration field 720 is a non-zero value (block 945=Non-zero value), the STA 240 releases the wireless medium at a time indicated by the non-zero value in block 955.

If it is determined the STA 240 woke up before the CF-End transmission (block 910=Before), the flow proceeds to block 920, where the STA 240 decodes the Release Channel subfield 710 of Frame Control field 705 of the CF-End frame 700. If the Release Channel subfield 710 is a first value (e.g., a zero) (block 930=First value), in block 935 the STA 240 resets the NAV and contends for wireless medium access. If the Release Channel field 710 is a second value (e.g., one) (block 930=Second value), in block 960, the STA 240 decodes the Duration field 720 of the CF-End frame 700. If the value of the Duration field 720 is a zero value (block 965=Zero value), the STA 240 in block 975 resets the NAV and contends for wireless medium access immediately. If the value of the Duration field 720 is a non-zero value (block 965=Non-zero value), in block 970, the STA 240 sets a time to next NDP CTS frame transmission, e.g., or a Beacon frame transmission. At the next NDP CTS frame transmission (e.g., or Beacon frame transmission), the STA 240 can determine at that time whether to contend for the wireless medium. That is, contention for access to the wireless medium should not begin until at least after a time period corresponding to the non-zero value has elapsed. For instance, after the end of the non-zero value of the Duration, the NDP CTS frame (e.g., or Beacon frame) is transmitted; the non-zero value indicates time to next NDP CTS frame transmission. Hence, STAs may not contend for channel after the end of the non-zero time.

Embodiments of the present invention may be implemented in software (executed by one or more processors), hardware (e.g., an application specific integrated circuit), or a combination of software and hardware. In an example embodiment, the software (e.g., application logic, an instruction set) is maintained on any one of various conventional computer-readable media. In the context of this document, a “computer-readable medium” may be any media or means that can contain, store, communicate, propagate or transport the instructions for use by or in connection with an instruction execution system, apparatus, or device, such as a computer, with one example of a computer described and depicted, e.g., in FIG. 2A. A computer-readable medium may comprise a computer-readable storage medium (e.g., memory(ies) 455, 425 or other device) that may be any media or means that can contain or store the instructions for use by or in connection with an instruction execution system, apparatus, or device, such as a computer. However, the computer-readable storage medium does not encompass propagating signals.

If desired, the different functions discussed herein may be performed in a different order and/or concurrently with each other. Furthermore, if desired, one or more of the above-described functions may be optional or may be combined.

Although various aspects of the invention are set out in the independent claims, other aspects of the invention comprise other combinations of features from the described embodiments and/or the dependent claims with the features of the independent claims, and not solely the combinations explicitly set out in the claims.

It is also noted herein that while the above describes example embodiments of the invention, these descriptions should not be viewed in a limiting sense. Rather, there are several variations and modifications which may be made without departing from the scope of the present invention.

The following abbreviations that may be found in the specification and/or the drawing figures are defined as follows:

- μs microseconds
- AC Access Category
- AIFSN Arbitration Inter-Frame Spacing-Number
- AP Access Point
- BSS Basic Service Set
- BSSID Basic Service Set Identifier
- CF Contention Free
- CSMA-CA Carrier Sense Multiple Access-Collision Avoidance
- CTS Clear to send
- DARPA Defense Advanced Research Projects Agency
- DCF Distributed Coordination Function
- DIFS DCF Interframe Space
- dB decibels
- DCF Distributed Coordination Function
- DIFS Distributed (coordination function) Interframe Space
- EDCA Enhanced Distributed Contention Access
- ETSI European Telecommunications Standards Institute,
- FCC Federal Communications Commission
- IFS Interframe Sensing
- km kilometer
- KW kilowatt
- LAN Local Area Network
- LTE Long Term Evolution
- MAC Medium Access Control
- ms milliseconds
- NAV Network Allocation Vector
- NDP Null Data Packet
- PCAST Presidential Council of Advisory for Science and Technology
- QoS Quality of Service
- RA Receiver Address or receiving station address
- SSPARC Shared Spectrum Access of Radar Bands by Communications
- STA Station, a wireless device
- TA Transmitter Address or transmitting station address
- TDD Time Division Duplex
- TxOP Transmission Opportunity
- UL uplink
- Wi-Fi Wireless Fidelity, a wireless local area network (and products) that are based on the Institute of Electrical and Electronics Engineers (IEEE) 802.11 standards
- WLAN Wireless Local Area Network

	Number	Date	Country
Parent	14080008	Nov 2013	US
Child	14146902		US

ENABLING COEXISTENCE BETWEEN WIRELESS NETWORKS AND RADAR SYSTEMS

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CPC

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Abstract

Description

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CROSS-REFERENCE TO RELATED APPLICATIONS

Continuations (1)