Method and apparatus for avoiding interference among multiple radios

Description

CROSS-REFERENCE TO RELATED APPLICATION

This present disclosure claims priority to U.S. Provisional Patent Application Ser. No. 61/540,162 filed Sep. 28, 2011, the disclosure of which is incorporated by reference herein in its entirety.

BACKGROUND

The background description provided herein is for the purpose of generally presenting the context of the disclosure. Work of the presently named inventors, to the extent it is described in this background section, as well as aspects of the description that may not otherwise qualify as prior art at the time of filing, are neither expressly nor impliedly admitted as prior art against the present disclosure.

Computing devices often communicate over multiple wireless networks to exchange data or access services. Each of these wireless networks typically operates within one or more respective frequency bands. Computing devices often include multiple radios (e.g., co-existing radios) that support simultaneous communication in the different frequency bands of the respective wireless networks. Although most of these frequency bands do not overlap, some of the frequency bands may be very close or adjacent to one another.

Accordingly, signals from one radio of the computing device may interfere with communications of another radio of the computing device attempting to use an adjacent frequency band. For example, transmissions (or harmonics thereof) of a first radio near an edge of a frequency band may bleed into an adjacent frequency band and be received by a receiver of a second radio. The relative strength of the transmission (e.g., due to proximity of an antenna of the first to an antenna of the second radio) and sensitivity of the receiver may impair an ability of the second radio to receive signals in the second frequency band. This can degrade the performance of the second radio, resulting in reduced signal quality, signal strength, data throughput, or even loss of a communication link.

SUMMARY

This summary is provided to introduce subject matter that is further described below in the Detailed Description and Drawings. Accordingly, this Summary should not be considered to describe essential features nor used to limit the scope of the claimed subject matter.

Generally, this disclosure describes one or more aspects including a method for determining whether a communication channel of a first wireless interface of a device is adjacent to a frequency band in which a second wireless interface of the device is configured to communicate. The communication channel is one of a plurality of communication channels available to the first wireless interface and the first wireless interface is configured to communicate using one of the plurality of communication channels as selected by a base station with which the first wireless interface is associated. The method further includes altering channel measurement results prior to transmission by the first wireless interface to the base station effective to prevent the base station from selecting, for use by the first wireless interface, the communication channel adjacent to the frequency band in which the second wireless interface is configured to communicate.

Another method is described for determining whether a communication channel of a first wireless interface of a device is adjacent to a frequency band in which a second wireless interface of the device is configured to communicate. The communication channel is one of a plurality of communication channels available to the first wireless interface and the first wireless interface is configured to communicate using one of the plurality of communication channels as selected by a base station with which the first wireless interface is associated. The method further includes preventing the first wireless interface from transmitting a channel measurement report to the base station effective to prevent the base station from selecting, for use by the first wireless interface, the communication channel adjacent to the frequency band in which the second wireless interface is configured to communicate.

A system is described that is configured to determine whether any communication channels of a first wireless interface are adjacent to a frequency band in which a second wireless interface is configured to communicate. The first wireless interface is configured to use one of the plurality of communication channels selected by a base station with which the first wireless interface is associated. The system is further configured to alter channel measurement results prior to transmission by the first wireless interface to the base station effective to prevent the base station from selecting, for use by the first wireless interface, those of the plurality of communication channels that are determined to be adjacent to the frequency band in which the second wireless interface is configured to communicate.

The details of one or more implementations are set forth in the accompanying drawings and the description below. Other features and advantages will be apparent from the description and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In the figures, the left-most digit of a reference number identifies the figure in which the reference number first appears. The use of the same reference numbers in different instances in the description and the figures indicate like elements.

FIG. 1 illustrates an operating environment having wireless devices in accordance with one or more aspects.

FIG. 2 illustrates an example of devices of FIG. 1 communicating in accordance with one or more aspects.

FIG. 3 illustrates a method of altering channel measurement results transmitted to a base station.

FIG. 4 illustrates an example frequency band allocation of multiple wireless networks.

FIG. 5 illustrates a method of preventing a wireless interface from transmitting a channel measurement report to a base station.

FIG. 6 illustrates a method of responding to a request for a channel measurement report.

FIG. 7 illustrates a System-on-Chip (SoC) environment for implementing aspects of the techniques described herein.

DETAILED DESCRIPTION

Conventional techniques for mitigating interference between multiple radios (e.g., co-existing radios) often rely on filtering transmissions or isolating antennas to reduce interference between communications in adjacent frequency bands. Adding hardware filters or increasing antenna isolation, however, increases design cost and complexity. This disclosure describes apparatuses and techniques for avoiding interference among multiple radios. In one aspect, a first radio of a device may avoid using communication channels adjacent to a frequency band in which a second radio of the device is configured to communicate. By so doing, interference between the co-existing radios can be avoided potentially improving signal strength, signal quality, or data throughput associated with either or both co-existing radios.

The following discussion describes an operating environment, techniques that may be employed in the operating environment, and a System-on-Chip (SoC) in which components of the operating environment can be embodied. In the discussion below, reference is made to the operating environment by way of example only.

Operating Environment

FIG. 1 illustrates an example operating environment 100 having user-equipment devices 102 (UE devices 102) and base station device 104 (BS device 104), each of which are capable of communicating data, packets, and/or frames over a wireless link 106, such as a wireless-wide-area network (WWAN). UE devices 102 include smart-phone 108, tablet computer 110, laptop computer 112, and cellular broadband router 114 (broadband router 114). Although not shown, other configurations of UE devices 102 are also contemplated such as a desktop computer, server, wireless-modem card, mobile-internet device (MID), gaming console, mobile hotspot, access point, and so on.

Each UE device 102 includes a cellular transceiver 116 (e.g., cellular radio) and a non-cellular transceiver 118 (e.g., non-cellular radio) that provide wireless interfaces to handle various communication protocols, such as for example 3rd Generation Partnership Project Long-Term Evolution (3GPP LTE), Bluetooth™, or IEEE 802.11-2007, IEEE 802.11n, and the like. Cellular transceiver 116 may operate in a frequency band associated with a particular communication standard or protocol by which cellular transceiver 116 communicates. For example, when cellular transceiver 116 operates in an LTE network, one or more LTE frequency bands may be used for communication, such as LTE band 40 (2.3-2.4 GHz) or LTE band 7 (2.5-2.69 GHz). With respect to cellular networking, UE device 102 may also be referred to as a mobile station (MS). Each communication protocol or standard may define one or more frequency bands in which communication occurs as will be described in greater detail below. Further, each respective frequency band may include multiple communication channels through which signals may be transmitted and/or received. UE device 102 may communicate by transmitting and/or receiving signals through one or more of these multiple communication channels.

Cellular transceiver 116 may be embodied separately as a transmitter and receiver (not shown) or integrated (shown) and may be hardware combined with or separate from firmware or software. Cellular transceiver 116 functions as a wireless interface for communicating data of UE device 102. Cellular transceiver 116 may comprise any suitable type of cellular radio, such as an LTE radio, universal mobile telecommunications system (UMTS) radio, or worldwide interoperability for microwave access (WiMax) radio. Cellular transceiver 116 communicates data and/or control signal with BS device 104 via wireless connection 106. At least some communicative aspects of cellular transceiver 116, such as communication channel selection and handover decisions, are managed by BS device 104.

Non-cellular transceiver 118 may be embodied separately as a transmitter and receiver (not shown) or integrated (shown) and may be hardware combined with or separate from firmware or software. Non-cellular transceiver 118 functions as a wireless interface for communicating data of UE device 102. Alternately or additionally, UE devices 102 may include multiple non-cellular transceivers 118, such as a short-range wireless network transceiver and a wireless-local-area-network (WLAN) transceiver. Non-cellular transceiver 118 may operate in the industrial, science, and medical frequency band (ISM Band), which includes frequencies of 2.4-2.5 GHz. In some cases, non-cellular transceiver 118 may be embodied as a non-cellular receiver, such as a global position system (GPS) receiver. Non-cellular transceiver 118 may communicate with another non-cellular transceiver 118 of a peer UE device 102 or a network managing entity (e.g., access point, wireless router, or Pico-net controller).

UE devices 102 also include processor(s) 120, computer-readable storage media 122 (CRM 122), a channel measurement report generator (report generator 124), and a co-existing radio interference manager (interference manager 126). In one implementation interference manager 126 is embodied on CRM 122. CRM 122 may include any suitable memory or storage device such as random-access memory (RAM), static RAM (SRAM), non-volatile RAM (NVRAM), read-only memory (ROM), or Flash memory useful to store data of applications and/or an operating system of the UE device 102. Report generator 124 provides channel measurement reports that describe measured characteristics for a given communication channel. Interference manager 126 may alter results of channel measurement reports or activities associated with triggering and/or transmitting the channel measurement reports to a base station. How interference manager 126 is implemented and used varies and is described below.

UE devices 102 may be configured as endpoint devices in a cellular network, such as smart-phone 108, tablet computer 110, or laptop computer 112, which are configured to provide data access and/or services to a user by connecting to the cellular network to obtain network or Internet connectivity. Alternately or additionally, UE devices 102 may be configured to implement router-like functionality via a secondary wireless network. For example, broadband router 114 can access the Internet via cellular transceiver 116 and provide Internet connectivity to other devices associated with broadband router 114 via non-cellular transceiver 118 (e.g., a WLAN or short-range wireless network). In this particular example, broadband router 114 concurrently communicates over multiple wireless networks and extends services or functionalities of either network to entities of both networks.

Base station device 104 (BS device 104) manages a cell of a wireless network, such as a cellular network. With respect to cellular networking, BS device 104 may be configured as a base station transceiver (BTS), node base station (node B), or enhanced node B (eNB) of an LTE network. BS device 104 includes BS cellular transceiver 128, which provides a wireless interface to handle various communication protocols, such as those mentioned above and elsewhere herein. Although shown as a single transceiver, BS cellular transceiver 128 may be implemented as a separate transmitter and receiver, and may be hardware combined with or separate from firmware or software. BS device 104 also include BS processor(s) 130, BS computer-readable storage media 132 (member CRM 132), and cellular network controller 134 (network controller 134). In one implementation network controller 134 is embodied on BS CRM 132. BS CRM 132 may include any suitable memory or storage device such as static RAM (SRAM), ROM, or Flash memory useful to store data of applications and/or an operating system of BS device 104.

BS device 104 manages, via network controller 134, a cell of a wireless network, such as an LTE network. This includes managing communications of any UE devices 102 associated with BS device 104. The cell managed by BS device 104 may be one of multiple cells that form a coverage area of the wireless network. Each of the multiple cells is managed by a respective BS device 104, which is responsible for managing UE devices 102 within its cell. When UE device 102 is within range of two or more BS devices 104, the BS device 104 with which the UE device 102 is associated may determine whether to initiate a handover of the UE device 102 to another one of the BS devices 104.

Wireless link 106 may include a downlink portion for data communicated from BS device 104 to UE device 102 and an uplink portion for data communicated from UE device 102 to BS device 104. Wireless link 106 may use any suitable communication channel in accordance with a communication protocol by which cellular transceiver 116 operates. These communication channels may reside within particular frequency bands as designated by a communication protocol or standard. In some cases, the uplink and downlink portions of wireless link 106 use a same communication channel. In other cases, the uplink and the downlink portions of wireless link 106 use different communication channels. In such cases, particular uplink and downlink communication channels may be paired or associated for use in forming a wireless link 106.

BS device 104 may communicate data or control information with UE device 102 using wireless link 106. In some cases, UE device 102 may communicate with multiple BS devices 104 using different respective wireless links 106. In such cases, UE device 102 may associate with a serving BS device 104 from which UE device 102 receives data and controls information. While associated with a serving BS device 104, UE device 102 may communicate with other BS devices 104 within range. Each BS device 104 with which UE device 102 communicates may use different communication channels. For example, UE device 102 may measure signal strength, signal quality, or channel quality of a communication channel of another wireless link 106 formed with another BS device 104. The selection and use of communication channels varies and is described in greater detail below.

FIG. 2 illustrates an example of device environment 200 that includes laptop computer 112, which is in range of BS devices 104-1, 104-2, and 104-3. In this particular example, laptop computer 112 is associated with serving BS device 104-1 via wireless link 202. From serving BS device 104-1, laptop computer 112 is able to access data or services of Internet 204 via back haul link 206. Laptop computer 112 may also communicate with BS device 104-2 via wireless link 208 or BS device 104-3 via wireless link 210. Each wireless link 202, 208, and 210 implements a different communication channel for communications with each respective BS device 104-1, 104-2, and 104-3. These communication channels reside within one or more frequency bands in accordance with a particular communication protocol or standard by which cellular transceiver 116 of laptop computer 112 communicates.

Laptop computer 112 may also communicate with wireless printer 212 via wireless link 214 and wireless speakers 216 via wireless link 218. Wireless link 214 may be implemented by a non-cellular transceiver 118, such as a WLAN transceiver. Wireless link 218 may be implemented by another non-cellular transceiver 118, such as a short-range wireless network transceiver. Thus, in the context of device environment 200, laptop computer 112 may communicate concurrently over three different wireless networks. For example, laptop computer 112 can receive data via wireless link 202 of a cellular network, send a print job to wireless printer 212 via wireless link 214 of a WLAN, and transmit audio information to wireless speakers 216 via wireless link 218 of a short-range wireless network.

Communications of one wireless transceiver may interfere with communications of another. In some cases, cellular transceiver 116 may transmit using a communication channel (e.g. an LTE channel) adjacent to (or near) a frequency band (e.g. ISM band) of non-cellular transceiver 118. In such cases, a receiving circuit of non-cellular transceiver 118 may receive these transmissions of cellular transceiver 116 as interference. Alternately or additionally, non-cellular transceiver 118 may transmit using a frequency band (e.g., ISM band) that is adjacent (or near) a communication channel (e.g., an LTE channel) of cellular transceiver 116. A receiving circuit of cellular transceiver 116 may receive these transmissions of non-cellular transceiver 118 as interference. The unintended reception of transmissions from another co-existing radio is an example of co-existing radio interference.

As described above, laptop computer 112 may also communicate with BS device 104-2 via wireless link 208 or BS device 104-3 via wireless link 210. For example, between communications over wireless link 202, laptop computer 112 may communicate via wireless links 208 and 210. Communicating over wireless links 208 and 210 permits cellular transceiver 116 of laptop computer 112 to measure a quality of communication channels associated with wireless links 208 and 210. Report generator 124 can then provide a channel measurement report for the communication channels associated with wireless link 208 and/or wireless link 210.

This measurement report may be transmitted to serving BS device 104-1 for use in a handover process. Serving BS device 104-1 can use this measurement report to determine if a handover of laptop computer 112 to another BS device 104 (e.g., BS device 104-2 or 104-3) would improve communication performance. Thus, serving BS device 104-1 may determine that communications of laptop computer 112 would improve if implemented over a different communication channel and/or another wireless link 106 (e.g., wireless link 208 or 210). For example, a currently selected communication channel of cellular transceiver 116 may be subject to co-existing radio interference due to transmissions of a non-cellular transceiver 118. In such a case, serving BS device 104-1 would initiate a handover process to another BS device 104 that communicates using a different communication channel, such as BS device 104-2 or 104-3. These are but a few example aspects of implementing techniques for avoiding co-existing radio interference, which are described in greater detail below.

Techniques of Avoiding Interference Among Multiple Radios

The following discussion describes techniques of avoiding interference among multiple radios. These techniques can be implemented using the previously described environments or entities, such as interference manager 126 of FIG. 1 embodied on a UE device 102. These techniques include methods illustrated in FIGS. 3, 5, and 7, each of which is shown as a set of operations performed by one or more entities. These methods are not necessarily limited to the orders shown for performing the operations. Further, these methods may be used in conjunction with one another, in whole or in part, whether performed by the same entity, separate entities, or any combination thereof. In portions of the following discussion, reference will be made to operating environment 100 of FIG. 1 and entities of FIG. 2 by way of example. Such reference is not to be taken as limited to operating environment 100 and/or entities of FIG. 2 but rather as illustrative of one of a variety of examples.

FIG. 3 depicts a method 300 for altering channel measurements transmitted to a base station, including operations performed by interference manager 126 of FIG. 1.

At 302, it is determined that a communication channel of a first wireless interface of a device is adjacent to a frequency band in which a second wireless interface of the device is configured to communicate. The first wireless interface may include a cellular transceiver or a wireless-wide-area-network (WWAN) radio. The communication channel may be one of multiple channels available to the first wireless interface for use in communication. Communications of the first wireless interface may be managed by a base station with which the first wireless interface is associated (e.g. serving base station). In some cases, managing communications of the first wireless interface comprises selecting a communication channel or a base station with which the first wireless interface is to communicate. In such cases, selecting another channel for the first wireless interface may include selecting another base station as a serving base station.

The second wireless interface may include a short-range wireless network transceiver or a WLAN transceiver. Communications of the second wireless interface may be scheduled, pending, or ongoing in the frequency band in which the second wireless interface is configured to communicate. These communications may include transmissions and/or reception of data, which can be communicated concurrently with data of the first wireless interface. In some cases, frequency band(s) of the first wireless interface may be adjacent to or overlap frequency band(s) of the second wireless interface. Thus, particular communication channels of the first wireless interface may be adjacent to the frequency band of the second wireless interface.

As an example, consider laptop computer 112 in the context of FIG. 2, which shows laptop computer 112 communicating via wireless link 202 and wireless link 214. Assume here that a user of laptop 112 is accessing Internet 204 via wireless link 202, which is an LTE wireless link. Also assume the user has initiated a print job with wireless printer 212 via wireless link 214, which communicates using a WLAN channel (e.g., channel 1) of the 2.4 GHz band as defined by an IEEE 802.11 standard.

For visual clarity, various communication channels are shown in FIG. 4, which illustrates an example allocation of frequency bands of multiple wireless networks at 400. These frequency bands include LTE 40 band 402, LTE 7 uplink band 404, LTE 7 downlink band 406, and ISM band 408. As shown by FIG. 4, LTE 40 band 402 and LTE 7 uplink band 404 are adjacent to ISM band 408.

Here, cellular transceiver 116 of laptop computer 112 is configured to communicate using communication channel 410 and non-cellular transceiver 118 is configured to communicate using WLAN channel 412. As illustrated in FIG. 4, transmissions of WLAN channel 412 are adjacent to, and may interfere with, downlink communications of communication channel 410. Accordingly, interference manager 126 determines that communication channel 410 is adjacent to ISM band 408, and more specifically, WLAN channel 412. It is to be noted that interference manager 126 may make this determination based on communications pending, scheduled, or ongoing in an adjacent frequency band. Thus, in the case of pending or scheduled non-cellular communication, interference manager 126 can make this determination prior to the occurrence of co-existing radio interference.

At 304, a channel measurement report (e.g., results of a channel measurement) generated by the first wireless interface is altered. This channel measurement report includes information associated with the communication channel of the first wireless interface that is adjacent to the frequency band of the second wireless interface. In some cases, this channel measurement report may be generated responsive to a request from a serving base station to survey communication channels of other base stations. In other cases, the channel measurement report may be generated periodically or responsive to a triggering event. The request may be part of a handover process being performed by the serving base station.

Altering the channel measurement report may include altering parameters useful to perform the channel measurements or altering results produced by the channel measurements. Altering the parameters useful to perform the channel measurements can include altering a threshold or offset of a measurement triggering event. In some cases, these measurement triggering events are based on communication performance with the serving base station being better or worse than a predefined threshold. In other cases, the measurement triggering events are based on communication performance of another base being better than a predefined threshold or better than an offset relative to the performance of the serving base station.

Any two or more of these measurement triggering events may be logically combined, in order to trigger a channel measurement when communication performance with a serving base station falls below a threshold and communication performance with another base station rises above another threshold. Communication performance may be characterized using any suitable quality, such as signal strength, signal quality, signal-to-noise ratio, channel quality, data rates, data throughput, latency times, and the like. Accordingly, altering a threshold or offset of a measurement triggering event can change measurement reporting behavior of a wireless interface of a device.

Altering results produced by the channel measurements may include altering a reference signal received power (RSRP), reference signal received quality (RSRQ), or channel quality indicator (CQI). These channel measurement results may be altered by degrading the channel measurement results by a predefined factor. For example, an RSRP or RSRQ indicator may be reduced by a particular number of decibels (dB), such as by 3 dB or 5 dB.

In the context of the present example, assume serving BS device 104-1 transmits a channel measurement request via communication channel 410 to laptop computer 112. Cellular transceiver 116 then measures performance characteristics of communication channel 410 of wireless link 202 and communication channel 414 of wireless link 208. Report generator 124 provides, based on the measured performance characteristics, a channel measurement report.

Interference manager 126 then alters, based on the determination of operation 302, results of the channel measurement report that are associated with communication channel 410, which is adjacent to ISM band 408. The altered results of the channel indicate that communication channel 410 is impaired, even though the channel measurement may not indicate such (e.g., non-cellular transceiver 118 is not currently transmitting). It is to be noted and understood that performing a channel measurement is not requisite for generating a channel measurement report. In some aspects, report generator 124 is capable of generating a channel measurement report without measurements of the channel being performed. In these aspects, time and energy involved with actually performing the channel measurements can be conserved.

At 306, the altered channel measurement report is transmitted to the serving base station. This can be effective to prevent the serving base station from selecting, for use by the first wireless interface, the channel adjacent to the frequency band of the second wireless interface. By so doing, the serving base station can be caused to select a communication channel that is not adjacent to the frequency band of the second wireless interface thereby avoiding interference between the co-existing radios.

In some cases, the first wireless interface communicates with the serving base station using the communication channel adjacent to the frequency band of the second wireless interface. In such cases, altering the channel measurement results can be effective to cause the base station to initiate a handover of the first wireless interface to another base station that communicates via another one of the multiple communication channels. In other cases, the first wireless interface communicates with the serving base station using a communication channel that is not adjacent to the frequency band of the second wireless interface. In these cases, altering the measurement results can be effective to prevent the base station from initiating a handover to another base station that communicates via the communication channel adjacent to the frequency band of the second wireless interface.

Concluding the present example, laptop computer 112 transmits the altered channel measurement report to serving BS device 104-1. Here, the altered results associated with communication channel 410 are effective to cause serving BS 104-1 to initiate a handover of cellular transceiver 116 to BS device 104-2, which uses communication channel 414 for communication. By initiating a handover to another BS device 104, interference caused by transmissions of non-cellular interface 118 in ISM band 408 can be avoided when cellular transceiver uses communication channel 414.

FIG. 5 depicts a method 500 of preventing a wireless interface from transmitting a channel measurement report to a base station, including operations performed by interference manager 126 of FIG. 1.

At 502, a request for channel measurement reports is received from a base station. The request for the channel measurement report may be received via a wireless interface which is associated with the base station. This wireless interface may be a first wireless interface of a device that includes at least a second wireless interface, such as a device supporting multiple co-existing radios.

The request may include a carrier frequency and bandwidth information associated with the base station (e.g., serving base station) and/or neighboring base stations. In some cases, physical cell identifiers of the neighboring base stations are provided with the request. Furthermore, neighboring base stations may be identified by demodulating primary or secondary synchronization signals. Reference signals of the neighboring base stations may also be used for identification.

As an example, consider laptop computer 112 again in the context shown in FIG. 2, which shows laptop computer 112 communicating via wireless link 202 and wireless link 218. Assume here that a user of laptop 112 is streaming a movie from Internet 204 via wireless link 202, that is an LTE wireless link. Also assume that audio of the movie is transmitted to wireless speakers via wireless link 218, which is a short-range wireless network link, such as Bluetooth™ or another wireless personal-area-network (WPAN) protocol operating in the ISM band.

In the context of the present example, cellular transceiver 116 receives a request for a channel measurement report from serving BS device 104-1. In this particular example, the request includes a request for channel measurements for wireless link 202 and wireless link 210. In other aspects, however, a request for a channel measurement report may request information associated with any number of wireless links or neighboring base stations.

At 504, it is determined that a communication channel of the first wireless interface is adjacent to a frequency band in which a second wireless interface is configured to communicate. In some cases, the communication channel of the first wireless interface is near to, or overlapping, the frequency band of the second wireless interface. The communication channel may be an uplink, downlink, or bi-directional communication channel. The frequency band of the second wireless interface may be a frequency band used by other wireless interfaces of the device. For example, the device may include a WLAN radio and a WPAN radio, which are both configured to use the ISM band for communication.

The determination may be based on an indication or information received from the first wireless interface and the second wireless interface. In some cases, this information or indication may be responsive to a query performed by a communication arbiter or scheduler (e.g., interference manager 126). The indication may be conveyed as a real time signal or high layer software message between wireless interfaces and/or the communication arbiter or scheduler.

Continuing the ongoing example, interference manager 126 receives channel information from cellular transceiver 116 and non-cellular transceiver 118. For visual clarity, refer again to FIG. 4, which illustrates an example allocation of frequency bands for multiple wireless networks at 400. As described above, these frequency bands include various LTE and ISM frequency bands. These frequency bands include LTE 7 uplink band 404, which is adjacent to ISM band 408.

Here, cellular transceiver 116 of laptop computer 112 is configured to communicate using communication channels 416 (uplink) and 418 (downlink) of wireless link 202, and non-cellular transceiver 118 is configured to communicate using WPAN channel 420 of wireless link 218. Signals of WPAN channel 420 are adjacent to, and may be interfered with by, uplink communications of communication channel 422 of wireless link 210 (not currently selected for use). Nonetheless, interference manager 126 determines that communication channel 422 is adjacent to ISM band 408, and more specifically, WPAN channel 420.

At 506, transmission of a channel measurement report for a communication channel is prevented. This may be effective to prevent a handover of the first wireless interface to another base station that uses the communication channel. In some cases, preventing measurements of the communication channel is effective to prevent the transmission of the channel measurement report. The channel measurement report may be for the communication channel adjacent to the frequency band of the second wireless interface or another communication channel associated with the adjacent channel. For example, LTE uplink channels may be paired with a respective downlink channel. In order to prevent a particular uplink channel from being selected for use, a channel measurement report associated with a paired respective downlink channel may be altered or precluded from being transmitted.

Altering parameters of a measurement triggering event may prevent a channel measurement report from being transmitted. For example, altering a threshold or offset of a measurement triggering event may preclude the generation and/or transmission of a channel measurement report. These measurement triggering events may be based on communication performance of a serving base station being better or worse than a predefined threshold. In other cases, the measurement triggering events are based on communication performance of another base station being better than a predefined threshold or better than an offset relative to the performance of the serving base station.

Concluding the present example, interference manager 126 prevents cellular transceiver 116 of laptop 112 from transmitting a channel measurement report for communication channel 424 (downlink), which is paired with communication channel 422 (uplink). This is effective to prevent serving BS device 104-1 from initiating a handover to BS device 104-3, which uses communication channels 422 and 424 of wireless link 210 for communication. By so doing, cellular transceiver 116 continues to communicate via communication channels 416 and 418 which do not interfere with communications in ISM band 408, thereby avoiding co-existing radio interference.

FIG. 6 depicts a method 600 of responding to a request for a channel measurement report with an altered channel measurement report, including operations performed by interference manager 126 of FIG. 1.

At 602, a request for a channel measurement report is received from a base station. This request may be received by a first wireless interface of a device that includes at least a second wireless interface, such as a device supporting multiple co-existing radios. The request may include a carrier frequency and bandwidth information associated with the base station (e.g., serving base station) and/or neighboring base stations. In some cases, physical cell identifiers of the neighboring base stations are provided with the request. Furthermore, neighboring base stations may be identified by demodulating primary or secondary synchronization signals. Identification of neighboring base stations may also be determined by their respective reference signals.

At 604, it is determined if any communication channels of the first wireless interface are adjacent to a frequency band in which a second wireless interface of the device is configured to operate. The communication channel may be one of multiple channels available to the first wireless interface for use in communication. Communications of the first wireless interface may be managed by a serving base station with which the first wireless interface is associated. In some cases, managing communications of the first wireless interface comprises selecting a communication channel or a base station with which the first wireless interface is to communicate.

Optionally at 606, channel measurements are performed to provide a channel measurement report. Intra-frequency channel measurements may be performed during communication over a given wireless link with a serving base station. Inter-frequency channel measurements may be performed with other base stations during gaps of communication with the serving base station. Alternately, a channel measurement report may be fabricated without performing channel measurements, saving time and energy involved with actually performing the channel measurements.

At 608, results of the channel measurement report are altered to provide an altered channel measurement report. Specifically, results associated with those communication channels adjacent to the frequency band of the second wireless interface may be altered or degraded. Altering the results of the channel measurement report may include altering a reference signal received power (RSRP), reference signal received quality (RSRQ), or channel quality indicator (CQI). These channel measurement results may be altered by degrading the channel measurement results by a predefined factor. For example, an indication of RSRP or RSRQ may be reduced by a particular number of decibels (dB), such as by 3 dB or 5 dB.

At 610, the altered channel measurement report is transmitted to the base station. This can be effective to prevent the base station from selecting, for use by the first wireless interface, those communication channels adjacent to the frequency band of the second wireless interface. By so doing, the base station can be caused to select a communication channel that is not adjacent to the frequency band of the second wireless interface thereby avoiding interference between the co-existing radios.

Optionally at 612, handover instructions are received from the base station. These instructions may initiate a handover of the first wireless interface to another of the communication channels that is not adjacent to the frequency band of the second wireless interface. By so doing, the first wireless interface may avoid either receiving interference from transmissions of the second wireless interface or interfering with reception of the second wireless interface when transmitting.

System-on-Chip

FIG. 7 illustrates a System-on-Chip (SoC) 700, which can implement various embodiments described above. A SoC can be implemented in any suitable device, such as a video game console, IP enabled television, smart-phone, desktop computer, laptop computer, access point, wireless router, cellular broadband router, tablet computer, server, network-enabled printer, set-top box, printer, scanner, camera, picture frame, and/or any other type of device that may implement wireless connective technology.

SoC 700 can be integrated with electronic circuitry, a microprocessor, memory, input-output (I/O) logic control, communication interfaces and components, other hardware, firmware, and/or software needed to provide communicative coupling for a device, such as any of the above-listed devices. SoC 700 can also include an integrated data bus (not shown) that couples the various components of the SoC for data communication between the components. A wireless communication device that includes SoC 700 can also be implemented with many combinations of differing components. In some cases, these differing components may be configured to implement concepts described herein over a wireless connection, link, or interface.

In this example, SoC 700 includes various components such as an input-output (I/O) logic control 702 (e.g., to include electronic circuitry) and a microprocessor 704 (e.g., any of a microcontroller or digital signal processor). SoC 700 also includes a memory 706, which can be any type and/or combination of RAM, low-latency nonvolatile memory (e.g., Flash memory), ROM, one-time programmable memory, and/or other suitable electronic data storage. Alternately or additionally, SoC 700 may comprise a memory interface for accessing additional or expandable off-chip memory, such as an external Flash memory module. SoC 700 can also include various firmware and/or software, such as an operating system 708, which can be computer-executable instructions maintained by memory 706 and executed by microprocessor 704. SoC 700 may also include other various communication interfaces and components, communication components, other hardware, firmware, and/or software.

SoC 700 includes cellular transceiver 116, non-cellular transceiver 118, report generator 124, and interference manager 126 (embodied as disparate or combined components as noted above). In other aspects, SoC 700 may include data interfaces to cellular transceiver 116 and/or non-cellular transceiver 118 when either of the transceivers is embodied separately from SoC 700. These data interfaces may communicate data or control signals associated with a respective transceiver, enabling SoC 700 to monitor and/or control activities of the respective transceiver. Thus, even when embodied separately, SoC 700 may implement aspects of techniques described herein using separate transceivers (e.g., acting as communication arbiter). Examples of these various components, functions, and/or entities, and their corresponding functionality, are described with reference to the respective components of the environment 100 shown in FIG. 1 and FIG. 2.

Interference manager 126, either independently or in combination with other entities, can be implemented as computer-executable instructions maintained by memory 706 and executed by microprocessor 704 to implement various embodiments and/or features described herein. Interference manager 126 may also be integrated with other entities of the SoC, such as integrated with one or both of I/O logic controller 702 or any packet-based interface within SoC 700. Alternatively or additionally, interference manager 126 and the other components can be implemented as hardware, firmware, fixed logic circuitry, or any combination thereof that is implemented in connection with the I/O logic control 702 and/or other signal processing and control circuits of SoC 700.

Although the subject matter has been described in language specific to structural features and/or methodological operations, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or operations described above, including orders in which they are performed.