Abstract: Methods, devices and systems for dynamic scheduling of Wi-Fi or Bluetooth signals based at least in part on LTE schedules are disclosed. In some examples, Wi-Fi or Bluetooth can perform coexistence decisions including Wi-Fi and Bluetooth channel or Adaptive Frequency Hopping (AFH) selection based on modem calculated Rx or Tx indications and device geo location, maximum allowed transmit power per channel for Wi-Fi, and the LTE modem connection state.

Abstract: Some demonstrative embodiments include devices, systems and methods of controlling communications of a multi-radio device. For example, a multi-radio device may include a cellular controller to control communication of a cellular radio; and a BT controller to control a transmission power of a BT radio according to a first power level, the BT controller is to receive from the cellular controller an indication of a cellular downlink period, and, during the cellular downlink period, to restrict a transmission power of at least one BT discovery packet to no more than a second power level, which is less than the first power level.

Abstract: Some demonstrative embodiments include devices, systems and methods of controlling communications of a multi-radio device. For example, a multi-radio device may include a first radio to communicate over a first wireless network; a first controller to control the first radio; a second radio to communicate over a second wireless network; a second controller to control the second radio; and an interface to communicate signaling messages between the first and second controllers, wherein the first controller is to send to the second controller a request to transmit, the request to transmit indicating a request to allow the first radio to transmit over the first wireless network, and wherein the second controller is to assert a transmit-allowed signal over the interface to indicate that the request to transmit is granted, or to de-assert the transmit-allowed signal to indicate that the request to transmit is denied.

Abstract: Methods, devices and systems for dynamic scheduling of Bluetooth signals based at least in part on LTE schedules are disclosed. In some examples, Bluetooth can deduce information on the LTE DL/UL activity based at least in part on the LTE frame structure, LTE decision point or the LTE subframe boundary time. In some examples, Bluetooth scheduler can dynamically change the timing of the scheduling algorithm such that it may utilize the knowledge of LTE traffic and may at least partially avoid interference or evaluate the interference level.

Abstract: Methods, devices and systems for dynamic scheduling of Wi-Fi or Bluetooth signals based at least in part on LTE schedules are disclosed. In some examples, Wi-Fi or Bluetooth can perform coexistence decisions including Wi-Fi and Bluetooth channel or Adaptive Frequency Hopping (AFH) selection based on modem calculated Rx or Tx indications and device geo location, maximum allowed transmit power per channel for Wi-Fi, and the LTE modem connection state.

Abstract: Methods, devices and systems for dynamic scheduling of Bluetooth signals based at least in part on LTE schedules are disclosed. In some examples, Bluetooth can deduce information on the LTE DL/UL activity based at least in part on the LTE frame structure, LTE decision point or the LTE subframe boundary time. In some examples, Bluetooth scheduler can dynamically change the timing of the scheduling algorithm such that it may utilize the knowledge of LTE traffic and may at least partially avoid interference or evaluate the interference level.

Abstract: Some demonstrative embodiments include devices, systems and methods of controlling communications of a multi-radio device. For example, a multi-radio device may include a cellular controller to control communication of a cellular radio; and a BT controller to control a transmission power of a BT radio according to a first power level, the BT controller is to receive from the cellular controller an indication of a cellular downlink period, and, during the cellular downlink period, to restrict a transmission power of at least one BT discovery packet to no more than a second power level, which is less than the first power level.

Abstract: Some demonstrative embodiments include devices, systems and methods of controlling communications of a multi-radio device. For example, a multi-radio device may include a first radio to communicate over a first wireless network; a first controller to control the first radio; a second radio to communicate over a second wireless network; a second controller to control the second radio; and an interface to communicate signaling messages between the first and second controllers, wherein the first controller is to send to the second controller a request to transmit, the request to transmit indicating a request to allow the first radio to transmit over the first wireless network, and wherein the second controller is to assert a transmit-allowed signal over the interface to indicate that the request to transmit is granted, or to de-assert the transmit-allowed signal to indicate that the request to transmit is denied.

Abstract: Systems and methods for channel scanning for multirole device are disclosed. One implementation relates to a method for servicing functions by a multirole device. The method comprises dividing a channel scan over a plurality of channels into a plurality of channel scan time periods, and repeatedly time division multiplexing a time period for the servicing of one of a station (STA) function and an access point (AP) function, a time period for the servicing of the other of the STA function and the AP function, and a channel scan time period for each of the plurality of channel scan time periods.

Abstract: A wireless communication device includes a processing unit with first chip and second chip that operates in parallel with the first chip. The first chip transmits/receives data according to LTE. The second chip transmits/receives data over a WLAN. The processing unit determines access points (AP) through which data can be transmitted/received by the second chip over the WLAN; and identifies an optimal AP, based on factors including a determination, for each AP, of whether transmission/reception of data by the first chip according to the LTE standard, simultaneous to transmission/reception of data over the WLAN by the second chip, would decrease the overall throughput of the first and second chips. When the second chip is previously connected to the WLAN through any AP other than the optimal AP, the second chip is disconnected from the other AP, and it is connected to the WLAN through the optimal AP.

Abstract: A wireless communication device includes a processing unit with first chip and second chip that operates in parallel with the first chip. The first chip transmits/receives data according to LTE. The second chip transmits/receives data over a WLAN. The processing unit determines access points (AP) through which data can be transmitted/received by the second chip over the WLAN; and identifies an optimal AP, based on factors including a determination, for each AP, of whether transmission/reception of data by the first chip according to the LTE standard, simultaneous to transmission/reception of data over the WLAN by the second chip, would decrease the overall throughput of the first and second chips. When the second chip is previously connected to the WLAN through any AP other than the optimal AP, the second chip is disconnected from the other AP, and it is connected to the WLAN through the optimal AP.

Abstract: Systems and methods for channel scanning for multirole device are disclosed. One implementation relates to a method for servicing functions by a multirole device. The method comprises dividing a channel scan over a plurality of channels into a plurality of channel scan time periods, and repeatedly time division multiplexing a time period for the servicing of one of a station (STA) function and an access point (AP) function, a time period for the servicing of the other of the STA function and the AP function, and a channel scan time period for each of the plurality of channel scan time periods.

Abstract: One embodiment of the present invention includes a communication system. The communication system includes a plurality of multi-role wireless communication devices communicatively coupled to transmit and receive data between at least one network access point and between each other in a plurality of communication roles in a time-division multiplexed manner. At least one of the at least one network access point and at least one of the plurality of multi-role wireless communication devices can be configured to transmit a timing beacon configured to synchronize a time-division multiplexing of at least one corresponding communication role associated with each of the plurality of multi-role wireless communication devices.

Abstract: A method is provided of coordinating adjacent first and second wireless networks, comprising: receiving a signal at a controller on a wireless device, the received signal indicating an intended transmission state of the first network during a future time slot, the intended transmission state indicating whether or not the first network intends to transmit first data during the future time slot; transmitting second data in the second network to a remote device if the intended transmission state indicates that the first network does not intend to transmit first data during the future time slot; and controlling transmission of the second data in the second network such that the transmission ends during the future time slot in which the first network does not intend to transmit first data, with sufficient time remaining to allow the second network to receive a reply transmission from the remote device.

Abstract: A system for determining a frequency modulated audio output of a mobile communication device during a near field communication transaction includes a transceiver providing a first frequency modulated audio signal. The device also is configured to determine when the near field communication transaction is occurring; a memory configured to store a replacement sound; and a selection circuit coupled with the transceiver and the memory to select the replacement sound when the near field communication transaction is occurring and select the first frequency modulated audio signal when the near field communication transaction is not occurring. There is also a signal path coupled with the selection circuit and configured to provide a second frequency modulated signal based on the selection circuit. In this way, the replacement sound is the audio output when the NFC transaction is occurring and the regular audio is output when the NFC transaction is not occurring.

Abstract: A system for determining a frequency modulated audio output of a mobile communication device during a near field communication transaction includes a transceiver providing a first frequency modulated audio signal. The device also is configured to determine when the near field communication transaction is occurring; a memory configured to store a replacement sound; and a selection circuit coupled with the transceiver and the memory to select the replacement sound when the near field communication transaction is occurring and select the first frequency modulated audio signal when the near field communication transaction is not occurring. There is also a signal path coupled with the selection circuit and configured to provide a second frequency modulated signal based on the selection circuit. In this way, the replacement sound is the audio output when the NFC transaction is occurring and the regular audio is output when the NFC transaction is not occurring.