Systems, methods, and devices to prevent overheating from high performance device configurations in wireless networks

The invention claimed is: 1. A user equipment (UE) comprising: a transceiver to communicate through a wireless communication system; a thermal finite-state-automaton comprising logic, at least a portion of which includes circuitry, the thermal finite-state-automaton comprising a plurality of system states and transitions between the plurality of system states, one or more of the plurality of system states based on a combination of network parameters for communicating through the wireless communication system and UE processing parameters, the plurality of system states comprising: a default state for operation of the UE at a sustainable performance configuration level for the network parameters and the UE processing parameters to maintain a UE temperature below a first temperature threshold; a high state for operation of the UE during up to a maximum time duration at a peak performance configuration level for the network parameters and the UE processing parameters, the peak performance configuration level to exceed the sustainable performance configuration level; a recovery state for operation of the UE during at least a minimum time duration at a reduced performance configuration level for the network parameters and the UE processing parameters, the reduced performance configuration level being less than the sustainable performance configuration level; and an emergency shutdown state triggerable by the UE temperature exceeding a second temperature threshold, wherein the UE is configured to autonomously transition between one or more of the plurality of system states without first being reconfigured by the wireless communication network, and wherein the UE is configured to signal, through the transceiver to the wireless communication system, a change in a power preference indicator (PPI) bit upon an autonomous transition from the high state to the emergency shutdown state before the maximum time duration lapses, or from the high state to the recovery state after the maximum time duration lapses. 2. The UE of claim 1 , wherein the network parameters include one or more parameters selected from a group comprising a modulation type, a coding scheme, a UE category, an uplink data rate, and a downlink data rate. 3. The UE of claim 1 , further comprising a system on chip (SoC), wherein the UE processing parameters include one or more parameters selected from a group comprising ambient temperature, system temperature of the SoC, junction temperature of the SoC, printed circuit board (PCB) temperature of the SoC, UE front or back skin temperature, UE internal case temperature, processing frequency of the SoC, number of activated power domains in the SoC, SoC current levels, SoC voltage levels, SoC chip process information, and SoC thermal budget. 4. The UE of claim 1 , wherein at least one of the default state, the high state, and the recovery state is based on a UE category associated with the UE. 5. The UE of claim 1 , wherein the UE is configured to communicate a UE capability profile through the transceiver to a node in the wireless communication system to configure one or more of the plurality of system states, the UE capability profile comprising one or more of: a default state capability profile to configure one or more of the network parameters and the UE processing parameters to maintain the UE temperature below the first temperature threshold; a high state capability profile to configure one or more of the network parameters and the UE processing parameters to operate at the peak performance configuration level; and a recovery capability profile to configure one or more of the network parameters and the UE processing parameters to prevent the UE temperature from exceeding the second temperature threshold. 6. The UE of claim 5 , wherein the node comprises an evolved universal terrestrial radio access network (E-UTRAN) Node B (eNB) in a third generation partnership project (3GPP) network, and wherein the UE is configured to signal the UE capability profile upon attachment to the eNB. 7. The UE of claim 5 , wherein at least one of the network parameters and the UE processing parameters may be further configured by a user or the wireless communication system to select one or more of the first temperature threshold, the maximum time duration, the minimum time duration, the second temperature threshold, and a presumed ambient temperature. 8. The UE of claim 1 , wherein the plurality of thermal states further comprises: a low state for periodically alternating operation of the UE between the peak performance configuration of the high state and a lower performance configuration level; and one or more emergency states in addition to the emergency shutdown state, and wherein the UE is configured to signal, through the transceiver to the wireless communication system using a plurality of power preference indicator (PPI) bits, an indication of an autonomous transition from the high state to one of the other plurality of system states. 9. The UE of claim 8 , wherein the one or more emergency states in addition to the emergency shutdown state comprises an emergency transition to the recovery state to enable cool-down of the UE for a selected period of time until the network reconfigures the UE in the recovery state. 10. The UE of claim 1 , wherein the UE is configured to transition between one or more of the plurality of system states in response to being reconfigured by the wireless communication network, another UE in a device-to-device (D2D) context, or a user command. 11. The UE of claim 1 , wherein the UE is configured to transition between one or more of the plurality of system states based on a detected event, a selected application for execution by the UE, or a selected service provided by the wireless communication network. 12. The UE of claim 11 , wherein the UE is further configured to transition between one or more of the plurality of system states according to a pre-scheduled thermal state sequence or extended discontinuous transmission mode associated with the detected event, the selected application, or the selected service. 13. The UE of claim 1 , wherein a subset of interactions between the wireless communication system and the UE to indicate or cause a transition between one or more of the plurality of system states is included as a conformance test requirement for a UE category corresponding to the UE, and wherein during a conformance test of the UE, corresponding test conditions are implemented for one or more combinations of the network parameters and the UE processing parameters to confirm that the subset of interactions satisfy the conformance test requirement for the UE category. 14. A user equipment (UE) comprising: a transceiver to communicate through a wireless communication system; a thermal finite-state-automaton comprising logic, at least a portion of which includes circuitry, the thermal finite-state-automaton comprising a plurality of system states and transitions between the plurality of system states, one or more of the plurality of system states based on a combination of network parameters for communicating through the wireless communication system and UE processing parameters, the plurality of system states comprising: a default state for operation of the UE at a sustainable performance configuration level for the network parameters and the UE processing parameters to maintain a UE temperature below a first temperature threshold; a high state for operation of the UE during up to a maximum time duration at a peak performance configuration level for the network parameters and the UE processing parameters, the