Radio frequency coexistence in a multimodal device through channel blacklisting

1 . A method of improving radio frequency coexistence in a multimodal device comprising: selecting, at the multimodal device, a subset comprising at least one transmitter frequency channel (TFC) from among a set of TFCs associated with the multimodal device; transmitting, from the multimodal device, a transmission signal on each TFC of the selected subset; generating a power level measurement based on a signal received at the multimodal device during transmitting of the transmission signal at a receiving frequency channel (RFC) associated with the multimodal device; and identifying a self-interfering TFC from among the set of TFCs based on the selected subset and the generated power level measurement. 2 . The method of claim 1 , further comprising: generating blacklist data associated with the identity of the self-interfering TFC; generating a set of available TFCs by eliminating the self-interfering TFC identified in the blacklist data from the set of TFCs associated with the multimodal device; and transmitting an indication of the available TFCs. 3 . The method of claim 1 , wherein selecting the subset comprises: identifying each TFC in the set of TFCs associated with the multimodal device; and enabling for transmission each TFC in the set of TFCs. 4 . The method of claim 3 , wherein selecting the subset further comprises: identifying at least one blacklisted TFC based on a table of blacklist data; disabling each blacklisted TFC; and disabling one additional TFC that is not a blacklisted TFC. 5 . The method of claim 4 , wherein selecting the subset further comprises: dividing the set of TFCs into a first set of TFCs that cannot be blacklisted and a second set of TFCs that can be blacklisted; and identifying a third set of TFCs comprising every TFC from the second set of TFCs that is not identified as a blacklisted TFC; wherein the disabled additional TFC is selected from the third set of TFCs. 6 . The method of claim 5 , wherein identifying the self-interfering TFC comprises: calculating an excess received power based on a difference between the generated power level measurement value and a target value; and recording a calculated excess received power value such that the calculated excess received power value is indexed to the disabled additional TFC. 7 . The method of claim 5 , wherein selecting the subset further comprises: (i) enabling the disabled additional TFC; (ii) disabling a new disabled additional TFC that is selected from the third set of TFCs; and iteratively (i) enabling the disabled additional TFC and (ii) disabling the new disabled additional TFC until each TFC in the third set of TFCs has been disabled exactly once. 8 . The method of claim 7 , wherein identifying the self-interfering TFC comprises iteratively calculating, during iterative periods in which the new disabled additional TFC is disabled, a new excess received power value based on a difference between a new generated power level measurement and a target value. 9 . The method of claim 8 , wherein identifying the self-interfering TFC further comprises: determining a lowest single value of the iteratively calculated excess received power values; determining which TFC of the third set of TFCs is associated with the lowest single value of the iteratively calculated excess received power values; and identifying the TFC associated with the lowest single value of the iteratively calculated excess received power values. 10 . The method of claim 9 , wherein identifying the self-interfering TFC further comprises: determining whether the lowest single value of the iteratively calculated excess received power values is less than zero; and selecting a new subset in response to a determination that the lowest single value of the iteratively calculated excess received power values is not less than zero. 11 . The method of claim 1 , wherein transmitting the transmission signal comprises simultaneously transmitting a transmission signal at maximum transmission power on each TFC of the selected subset. 12 . The method of claim 1 , wherein generating the power level measurement comprises iteratively generating a power level measurement for each of a plurality of RFCs associated with the multimodal device. 13 . The method of claim 1 , wherein generating the power level measurement based on the signal received at the receiving frequency channel (RFC) associated with the multimodal device occurs simultaneously with transmitting the transmission signal on each TFC of the selected subset. 14 . The method of claim 1 , wherein: selecting a subset further comprises selecting a subset including TFCs within a frequency band associated with (i) second generation (2G), (ii) third generation (3G), (iii) fourth generation (4G), (iv) Long Term Evolution (LTE), (v) Wi-Fi, (vi) Bluetooth, or (vii) any combination of (i), (ii), (iii), (iv), (v), and (vi); and generating the power level measurement further comprises generating a power level measurement based on an RFC within a frequency band associated with (i) second generation (2G), (ii) third generation (3G), (iii) fourth generation (4G), (iv) Long Term Evolution (LTE), (v) Wi-Fi, (vi) Bluetooth, or (vii) any combination of (i), (ii), (iii), (iv), (v), and (vi). 15 . An apparatus for improving radio frequency coexistence in a multimodal device, comprising: means for selecting, at the multimodal device, a subset comprising at least one transmitter frequency channel (TFC) from among a set of TFCs associated with the multimodal device; means for transmitting, from the multimodal device, a transmission signal on each TFC selected by the means for selecting a subset; means for generating a power level measurement based on a signal received at the multimodal device during transmitting of the transmission signal at a receiving frequency channel (RFC) associated with the multimodal device; and means for identifying a self-interfering TFC from among the set of TFCs based on the subset selected by the means for selecting a subset and the power level measurement generated by the means for generating a power level measurement. 16 . The multimodal device of claim 15 , further comprising: means for generating blacklist data associated with the identity of the self-interfering TFC; means for generating a set of available TFCs by eliminating the self-interfering TFC identified in the blacklist data from the set of TFCs associated with the multimodal device; and means for transmitting an indication of the available TFCs. 17 . The multimodal device of claim 15 , wherein means for selecting a subset comprises: means for identifying each TFC in the set of TFCs associated with the multimodal device; and means for enabling for transmission each TFC in the set of TFCs. 18 . A non-transitory computer-readable medium storing code, which, when executed by a processor, causes the processor to perform operations for improving radio frequency coexistence in a multimodal device, the non-transitory computer-readable medium comprising: code for selecting, at the multimodal device, a subset comprising at least one transmitter frequency channel (TFC) from among a set of TFCs associated with the multimodal device; code for transmitting, from the multimodal device, a transmission signal on each TFC of the selected subset; code for generating a power level measurement based on a signal received at the multimodal device during transmitting of the transmission signal at a receiving frequency channel (RFC) associated with t