This disclosure relates generally to wireless power. More specifically, this application relates to fault detection a wireless power system.
A wireless power system may include a wireless power transmission apparatus (sometimes also referred to as a Power Transmitter, or PTx) and a wireless power reception apparatus (sometimes also referred to as a Power Receiver, or PRx). For example, the wireless power transmission apparatus may be installed on or included in a countertop or other flat surface. The wireless power reception apparatus may be included in a cordless appliance, such as a blender, a kettle, an air fryer, a mixer, or a toaster, among other examples. The wireless power transmission apparatus may include a primary coil that produces an electromagnetic field that may induce a voltage in a secondary coil of the wireless power reception apparatus when the secondary coil is placed in proximity to the primary coil. In this configuration, the electromagnetic field may wirelessly transfer power to the secondary coil. The power may be transferred using inductive coupling or resonant coupling between the primary coil and the secondary coil. The wireless power reception apparatus may provide the received power to operate the cordless appliance.
The systems, methods, and apparatuses of this disclosure each have several innovative aspects, no single one of which is solely responsible for the desirable attributes disclosed herein.
One innovative aspect of the subject matter described in this disclosure can be implemented as a method by a wireless power transmission apparatus (Power Transmitter) of a wireless power system. The method includes receiving information from a Power Receiver related to an operation of the Power Receiver. The method includes determining an energy requirement of the Power Receiver based, at least in part, on the information. During a power transfer phase, the method includes periodically receiving power control communications from the Power Receiver, transmitting wireless power to the Power Receiver. The method includes, during the power transfer phase, ceasing transmission of wireless power by the Power Transmitter when an unexpected power control communication is received from the Power Receiver after a total amount of energy transferred to the Power Receiver exceeds the energy requirement by a threshold amount.
Another innovative aspect of the subject matter described in this disclosure can be implemented as a Power Transmitter of a wireless power system. The Power Transmitter includes a communication unit configured to receive information from a Power Receiver related to an operation of the Power Receiver. The Power Transmitter includes a primary coil configured to transmit wireless power to the Power Receiver during a power transfer phase. The communication unit is configured to periodically receive power control communications from the Power Receiver during the power transfer phase. The Power Transmitter includes a transmission controller configured to determine an energy requirement of the Power Receiver based, at least in part, on the information, cease transmission of wireless power to the Power Receiver when an unexpected power control communication is received from the Power Receiver after a total amount of energy transferred to the Power Receiver exceeds the energy requirement by a threshold amount.
Details of one or more implementations of the subject matter described in this disclosure are set forth in the accompanying drawings and the description below. Other features, aspects, and advantages will become apparent from the description, the drawings, and the claims. Note that the relative dimensions of the following figures may not be drawn to scale.
Note that the relative dimensions of the figures may not be drawn to scale.
The following description is directed to certain implementations for the purposes of describing innovative aspects of this disclosure. However, a person having ordinary skill in the art will readily recognize that the teachings herein can be applied in a multitude of different ways. The described implementations can be implemented in any means, apparatus, system, or method for transmitting or receiving wireless power.
A wireless power system may include a wireless power transmission apparatus (sometimes referred to as a Power Transmitter, or PTx) integrated with or otherwise disposed on a surface. The wireless power system also may include a wireless power reception apparatus (sometimes referred to as a Power Receiver, or PRx). The wireless power transmission apparatus may include a primary coil configured to wirelessly transmit power via a magnetic field to a secondary coil in the wireless power reception apparatus. In some implementations, the wireless power transmission apparatus may include a countertop-mounted primary coil or a primary coil that is embedded or manufactured in a surface on which a cordless appliance can be placed. The cordless appliance may include a wireless power reception apparatus for wirelessly receiving power. A secondary coil of the wireless power reception apparatus may obtain wireless energy from the magnetic field and provide it to a power receiving circuit. The power receiving circuit may convert the energy and utilize it to charge or power a load. A wireless power reception apparatus may be included or integrated with a cordless appliance having a variable load (such as a blender, heating element, a fan, among other examples).
During a power transfer phase, the wireless power reception apparatus may periodically communicate power control communication to the wireless power transmission apparatus via a communication channel. The power control communications may indicate presence or status, among other examples. For example, the power control communications may include a power request, a null communication (to indicate presence without feedback), or power receiver feedback. In some circumstances, the communication channel may continue to function properly despite a failure associated with the wireless power reception apparatus. For example, the wireless power transmission apparatus and the wireless power reception apparatus may communicate via Near Field Communication (NFC), BluetoothTM, or other communications technique that could continue to function even when power transfer circuits have failed. Thus, in some scenarios, the wireless power reception apparatus may continue to communicate power control communications from the wireless power transmission apparatus via the communication channel even when all or part of a power receiving circuit in the wireless power reception apparatus is not functioning properly. The wireless power transmission apparatus may protect itself and the cordless appliance from an abnormal condition. Examples of abnormal conditions contemplated in this disclosure include a series element failure resulting in an open circuit (also referred to as a fault), a communication loss, or a corrupt control unit or sensor, among other examples. In some instances, a cordless appliance may not have the means to know if a heating element, a thermal fuse, or other element has failed, resulting in an open circuit in the appliance. Some types of cordless appliances (such as a water kettle, for example) may implement a basic control architecture (referred to as type 1) in which basic communication is independent from operations of the load. In some instances, a cordless appliance may experience a failure such as an open circuit failure of the load disconnect switch, an open diode in the converter, a blown fuse, or open relay contacts. Absent the techniques of this disclosure, the wireless power transmission apparatus would otherwise continue to transmit wireless power that is absorbed by metallic components of the wireless power reception apparatus. This can lead to overheating, damage to the wireless power reception apparatus, or fire, among other potentially dangerous outcomes.
This disclosure provides systems, methods and apparatuses for a wireless power transmission apparatus to detect a fault of the wireless power reception apparatus. Various implementations relate generally to fault protection in a wireless power system. In some aspects, a transmission (TX) controller of the wireless power transmission apparatus can detect a fault of the wireless power reception apparatus based on power transfer measurements or calculations in the wireless power transmission apparatus. The techniques may enable the wireless power transmission apparatus to detect faults such as an open circuit in the wireless power reception apparatus or a thermostat failure, among other examples. During the transmission of wireless power, the wireless power transmission apparatus may detect the fault and cease the transmission of wireless power. Using the techniques of this disclosure, the wireless power transmission apparatus can detect the fault regardless of whether the wireless power transmission apparatus receives power control communications from a communication unit of the wireless power reception apparatus.
In some aspects, a wireless power transmission apparatus may detect a fault (such as an open circuit fault) of the wireless power reception apparatus based on measurements at the wireless power transmission apparatus. For example, the wireless power transmission apparatus may obtain voltage and current measurements at a component (such as an inverter) of a power transmitter circuit. The wireless power transmission apparatus may calculate an average transmitter power based on the voltage and current measurements. In some implementations, the wireless power transmission apparatus may adjust the average transmitter power based on known characteristics of the wireless power transmission apparatus such as an expected power transmission loss associated with components of the wireless power transmission apparatus. The wireless power transmission apparatus can calculate a power transfer amount (sometimes also referred to as Transmitted Power) as a difference between the average transmitter power and the expected power transmission loss. When the power transfer amount is lower than expected (such as lower than a fault detection threshold), the wireless power transmission apparatus may determine that the wireless power reception apparatus has an open circuit fault in the receiver. The open circuit fault may include a fault in the power receiver circuit (such as at the load or a rectifier) in the wireless power reception apparatus. In some implementations, the power transfer amount may be based on measurements in the wireless power transmission apparatus so that the fault detection by the wireless power transmission apparatus is not dependent on a fault detection technique of the wireless power reception apparatus. When the power transfer amount is below a fault detection threshold, the wireless power transmission apparatus may suspect a fault in the wireless power reception apparatus.
In some aspects, the wireless power transmission apparatus may adjust one or more operating parameters (such as an operating frequency, an operating voltage, or an operating duty (sometimes also referred to as a duty cycle), among other examples) and determine whether the power transfer amount remains below the fault detection threshold. The wireless power transmission apparatus may determine the fault based on one instance or a plurality of instances when the power transfer amount is below the fault detection threshold. Each instance may be an indication of the fault. In some implementations, the wireless power transmission apparatus may attempt different operating parameters over a fault detection time period. The wireless power transmission apparatus may determine the fault after a threshold quantity of indications or after the fault detection time period during which the power transfer amount remains below the fault detection threshold.
In some aspects, a wireless power transmission apparatus may detect a fault (such as a thermostat failure) of the wireless power reception apparatus based on measurements at the wireless power transmission apparatus. The wireless power reception apparatus may have a thermostat (such as a bimetallic element) that is configured to detect overheating. However, when the thermostat fails to detect the overheating, a communication unit of the wireless power reception apparatus may continue to request power. Using the techniques of this disclosure, a wireless power transmission apparatus may estimate an energy requirement or a maximum power transmission time that should be adequate for an operation of the wireless power reception apparatus. Before a power transfer phase, the wireless power reception apparatus may communicate information regarding the operation (such as boiling water, toasting bread, or cooking time, among other examples). The information may include parameters such as a power rating, typical time for the operation, an energy request, among other examples. The wireless power transmission apparatus may determine the energy requirement or the maximum power transmission time based on the information from the wireless power reception apparatus. In some implementations, the energy requirement or the maximum power transmission time also may be based on one or more operating parameters of the wireless power transmission apparatus. Once the wireless power transmission apparatus has transmitted wireless power to satisfy the energy requirement or the maximum power transmission time, the wireless power transmission apparatus may receive an unexpected power control communication. For example, the wireless power transmission apparatus may receive a power command or feedback message from the wireless power reception apparatus that would otherwise be associated with a request for continued transmission of wireless power. In some implementations, the wireless power transmission apparatus may detect a fault of the wireless power reception apparatus in response to receiving the unexpected power control communication from the wireless power reception apparatus after a total amount of energy transferred to the wireless power reception apparatus exceeds the energy requirement by a threshold amount. In some implementations, the wireless power transmission apparatus may detect a fault of the wireless power reception apparatus in response to receiving the unexpected power control communication from the wireless power reception apparatus after a total power transmission time exceeds the maximum power transmission time.
In some aspects, the wireless power transmission apparatus may implement one or more fault handling actions. In some implementations, the wireless power transmission apparatus may communicate a fault message to the wireless power reception apparatus. The wireless power reception apparatus may cease operation of a load, provide a user interface indication of the fault, or otherwise react to the fault message to prevent a potentially dangerous situation that would otherwise result from continued wireless power transfer.
Particular implementations of the subject matter described in this disclosure can be implemented to realize one or more of the following potential advantages. A fault of the wireless power reception apparatus may be detected by the wireless power transmission apparatus to prevent overheating, damage, or fire. The fault detection described in this disclosure can supplement or replace fault detection techniques performed by the wireless power reception apparatus. Even if the wireless power reception apparatus has fault detection techniques, those receiver-side techniques may fail. Thus, transmitter-side techniques for detecting a fault of the wireless power reception apparatus may improve the safety of the wireless power system.
While the examples in this disclosure are based on wireless power used in kitchen systems, the techniques are applicable to other types of systems. For example, the techniques may be used with wireless power systems associated with home appliances, electronic devices, fans, space heaters, speaker systems, air compressors, garden equipment, or components of an electric vehicle, among other examples.
The wireless power system 100 includes a wireless power transmission apparatus 102 and a wireless power reception apparatus 118. The wireless power transmission apparatus includes a primary coil 104. The primary coil 104 may be associated with a power transmitter circuit 106 (sometimes also referred to as a power signal generator). The primary coil 104 may be a wire coil which transmits wireless power (which also may be referred to as wireless energy). The primary coil 104 may transmit wireless energy using inductive or magnetic resonant field. The power transmitter circuit 106 may include components (not shown) to prepare the wireless power. For example, the power transmitter circuit 106 may include one or more switches, drivers, series capacitors, rectifiers, inverters, or other components.
In some implementations, the power transmitter circuit 106, TX controller 108 and other components (not shown) may be collectively referred to as a power transmitter unit 110. Some or all of the power transmitter unit 110 may be embodied as an integrated circuit (IC) that implements features of this disclosure for controlling and transmitting wireless power to one or more wireless power reception apparatuses. The TX controller 108 may be implemented as a microcontroller, dedicated processor, integrated circuit, application specific integrated circuit (ASIC) or any other suitable electronic device.
The power source 112 may provide power to the power transmitter unit 110 in the wireless power transmission apparatus 102. In some implementations, the power source 112 may convert alternating current (AC) power to direct current (DC) power. For example, the power source 112 may include a converter that receives an AC power from an external power supply and converts the AC power to a DC power used by the power transmitter circuit 106. Alternatively, or additionally, a component (such as an inverter) of the power transmitter circuit 106 may converter the AC power to the DC power.
The TX controller 108 is connected to a first communication interface 114. The first communication interface 114 is connected to a first communication coil 116. In some implementations, the first communication interface 114 and the first communication coil 116 may be collectively referred to as the first communication unit 124. In some implementations, the first communication unit 124 may support Near-Field Communication (NFC). NFC is a technology by which data transfer occurs on a carrier frequency of 13.56 Megahertz (MHz). The first communication unit 124 also may support any suitable communication protocol.
The wireless power reception apparatus 118 may include a secondary coil 120, a rectifier 126, a reception (RX) controller 128, a second communication interface 132, a load controller 136, a load 130, and a memory (not shown). In some implementations, the load 130 may also include a drive (not shown) for controlling at least one parameter such as speed or torque of the load. In some implementations, the rectifier 126 may be omitted. In some implementations, a series switch (not shown) may be included in series with the secondary coil 120. Although shown as different components, some components may be packaged or implemented in the same hardware. For example, in some implementations, the RX controller 128 and the load controller 136 may be implemented as a single controller. The RX controller 128, the load controller 136, or any combination thereof, may be implemented as a microcontroller, dedicated processor, integrated circuit. application specific integrated circuit (ASIC) or any other suitable electronic device.
The TX controller 108 may detect the presence or proximity of a wireless power reception apparatus 118. This detection may happen during a periodic pinging process of the first communication interface 114 in the wireless power transmission apparatus 102. During the pinging process, the first communication interface 114 also may supply power (via the first communication coil 116) to the second communication interface 132 (via the second communication coil 134) when the wireless power reception apparatus 118 is in proximity. The second communication interface 132 may “wake up” and power-up the RX controller 128 and may send a reply signal back to the first communication interface 114. Prior to power transfer, a handshaking process may take place during which the TX controller 108 may receive data configuration related to the power rating of the receiver, among other information.
Different cordless appliances have different load types, different load states, and different power requirements or may require power at a particular voltage and frequency. For example, a cordless blender may include a variable motor load that has multiple user-selectable load states to control motor speed. In some implementations, a cordless appliance may have user-selectable load states or user-selectable load patterns of operation. Depending on the load state, the cordless blender may require different levels of power to operate. In another example, a cordless kettle may include a resistive load that has different load states to control temperature. In yet another example, an air fryer may be a compound load device and may operate a heater, a fan, or both, at various periods of operation. Each type of load (such as the motor, the resistive load, the heater, the fan, or any combination thereof) may require different amounts of power to operate based on a current load state or load state. Furthermore, cordless appliances may exhibit different levels of voltage gains from a primary coil to a receiver coil at different primary coil excitation frequencies (such as a wireless power transfer frequency) depending on their load type or load state. For example, to achieve a desired load voltage, a cordless blender may operate best at a first operating frequency for a first load state, such as a low motor speed setting. However, as the load state changes, the cordless blender may not achieve the same load voltage when operated at the first operating frequency. For example, the first operating frequency may facilitate a first voltage gain when the cordless blender is set to a first load state (such as a low-speed setting), but the first operating frequency may provide a lower voltage gain when the cordless blender is set to a second setting (such as a higher-speed setting).
Another factor that may alter voltage gain is based on an alignment of the secondary coil 120 and the primary coil 104 during power transfer. Voltage gain may be measured in terms a ratio of voltage received by the secondary coil 120 to voltage applied at the primary coil 104. Wireless power transmission is more efficient when the primary and secondary coils are optimally aligned. Conversely, the efficiency may decrease (or the power transmission may cease) when the primary and secondary coils are misaligned. When properly aligned, primary coils and secondary coils can transfer wireless energy up to an amount predetermined by a wireless standard. For example, with proper alignment, a primary coil may convey power ranging from 30 Watts (W) up to 2.2 Kilowatts (KW). Because alignment affects the efficiency of power transmission, the wireless power transmission apparatus may modify the amount of wireless power based on its alignment with the wireless power reception apparatus.
The TX controller 108 may control characteristics of wireless power it provides to the wireless power reception apparatus 118. After detecting the wireless power reception apparatus 118, the TX controller 108 may receive configuration data from a wireless power reception apparatus 118. For example, the TX controller 108 may receive the configuration data during a hand shaking process with the wireless power reception apparatus 118.
In some implementations, the wireless power reception apparatus 118 may be included in a cordless appliance, such as a cordless blender, cordless kettle, cordless juicer, etc. The wireless power reception apparatus 118 may include a secondary coil 120, a rectifier 126, and an RX controller 128. When the secondary coil 120 is aligned to the primary coil 104, the secondary coil 120 may generate an induced voltage based on a received wireless power signal from the primary coil 104. A capacitor may be in series between the secondary coil 120 and the rectifier 126. The rectifier 126 may rectify the induced voltage and provide the induced voltage to a load 130. The load 130 may be any suitable load such as a variable motor load, variable resistive load or a variable induction heating load. The load may include an additional electronic drive (not shown).
A RX controller 128 may be operationally coupled to the rectifier 126 and the second communication interface 132. The second communication interface 132 may contain modulation and demodulation circuits to wirelessly communicate via the second communication coil 134. Thus, the RX controller 128 may wirelessly communicate with the feedback controller 122 via the second communication interface 132 to the first communication interface 114 using NFC communications. Alternatively, or additionally, the RX controller 128 may use load modulation to communicate via an in-band communication link (not shown) that includes the secondary coil 120.
A load controller 136 may be operationally coupled to the load 130 and the second communication interface 132. The load controller 136 may detect changes to load states. For example, the load controller 136 may detect changes to user-selectable load states, such as temperature selectors and motor speed selectors. The load controller 136 also may determine a load voltage reference and load state based on the power estimate. The load controller 136 also may provide load states, load voltage references and any other suitable information to the RX controller 128 or the second communication interface 132 for communication to the wireless power transmission apparatus 102. The RX controller 128 may additionally determine and provide feedback information indicating a measured load voltage available to the load 130. In some feedback messages, the feedback information may include a reference voltage indicating a required voltage for the load 130. In some feedback messages, the feedback information may include the required power for the load. Although the RX controller 128 and load controller 136 are shown separately. they may be included in the same component of the wireless power reception apparatus 118.
In some implementations, as a preparation step for a wireless power transmission, the wireless power transmission apparatus 102 may optionally transmit an information request signal to the wireless power reception apparatus (S210). The information request signal may be a signal for requesting an ID and request power information of the wireless power reception apparatus 118. As an example, the information request signal may
be transmitted in a form of data packet message. As another example, the information request signal may be transmitted in a form of digital ping according to a predefined standard between the wireless power transmission apparatus 102 and the wireless power reception apparatus 118. In response to the information request signal, the wireless power reception apparatus 118 may optionally transmit the ID and configuration information to the wireless power transmission apparatus 102 (S220). For example, the configuration information may include a requested amount of power or a maximum amount of power that is provided for the wireless power reception apparatus 118. In some implementations, the configuration information may include a rated power value associated with the load or an operation of the load. In some implementations, the configuration information also may include a time parameter. For example, the time parameter may indicate an expected time for the wireless power reception apparatus to complete the operation based on the rated power value. In some implementations, the information request signal and the ID and configuration information may be communicated using out-of-band communication (separate from the wireless power signal) such as NFC or Bluetooth.
Based on the ID and configuration information, the wireless power transmission apparatus 102 configures parameters (referred to as an operating point) for power transmission and performs a wireless power transmission to the wireless power reception apparatus 118 (S230). For example, the wireless power transmission apparatus may create a power transmission contract based on the ID and the configuration information and may control the wireless power transmission according to the power transmission contract. The process, performed by the wireless power transmission apparatus 102, from the start to the end of the wireless power transmission to the wireless power reception apparatus may be called a (wireless) power transfer phase 235. In some implementations, the wireless power reception apparatus 118 may provide the received wireless power to an external load such as a heating element, motor, or battery, among other examples. In some implementations, an operation of the wireless power reception apparatus 118 may be based on the external load and a user-configurable setting. For example, the operation may include boiling water, toasting bread, or cooking food. In other examples, the operation may be based on charging a battery or other energy storage device to a desired level.
The wireless power transmission apparatus 102 may monitor the parameters for power transmission and may abort the wireless power transmission when any one of the parameters exceeds a stated limit. Alternatively, the wireless power transmission process of S230 may be ended by a request of the wireless power reception apparatus 118. For example, the wireless power reception apparatus 118 may transmit a signal for requesting termination of the wireless power transmission to the wireless power transmission apparatus 102, when the operation of the wireless power reception apparatus 118 is complete.
During the power transfer phase 235, the wireless power reception apparatus 118 periodically transmits power control communications to the wireless power transmission apparatus 102 (shown at S240-1, S240-2, S240-3, and S240-4). Examples of a power control communication may include a control error packet (CEP), a power request message, or a status message, among other examples. This is performed for controlling an amount of power which is transmitted from the wireless power transmission apparatus 102 to the wireless power reception apparatus 118, that is, to perform a power control.
As described herein, there are circumstances in which the wireless power reception apparatus 118 may continue to transmit power control communications even though the receiver electronics of the wireless power reception apparatus 118 have failed. Since the power control communications may be transmitted by a communication unit via an out-of-band communication channel, the communication may be operational despite a hardware failure that could prevent the wireless power reception apparatus 118 from properly receiving and processing the wireless power. For example, the load (such as a heating element) may have an open circuit fault, electronics (such as rectifier) may have open circuit fault, a thermostat failure may fail to detect an overheating situation, or other failure in the receiver can result in a failure to process the wireless power transmission. Meanwhile, the wireless power reception apparatus 118 may continue to transmit power control communications that the wireless power transmission apparatus 102 may interpret as a request to continue transmitting wireless power. In accordance with this disclosure. the wireless power transmission apparatus 102 may detect such failures (S245) and act to cease wireless power transmission (S250). This disclosure includes several techniques by which the wireless power transmission apparatus 102 can detect a failure in the wireless power reception apparatus 118 regardless of whether the wireless power reception apparatus 118 continues to transmit power control communications.
The TX controller 108 may exchange communications with a wireless power reception apparatus via a communication unit. The communication unit may include a communication interface 326, a communication controller (not shown) or other component connected to a communication coil 328. In some implementation, the communication interface 326 and the communication coil 328 are configured to communicate using an NFC communication protocol. In some implementations, the communication interface 326 and the TX controller 108 may be collocated in a common processor or chip.
The TX controller 108 may detect the wireless power reception apparatus in proximity to the primary coil 322 and conduct a handshaking process during which the TX controller 108 receives information from the wireless power reception apparatus. The TX controller 108 may receive the information via the communication interface 326. In some implementations, the information may include one or more reference control parameters such as operating frequencies of the wireless power reception apparatus at different reference coupling factors (K-factors), load voltages and load powers of the wireless power reception apparatus. In some implementations, the information may indicate a load type and a load state for a variable load associated with the wireless power reception apparatus. Load state represents the combined state of load voltage and corresponding load power of the appliance. The TX controller 108 may utilize this information to provide wireless power having characteristics that enable the wireless power reception apparatus to operate. For example, the TX controller 108 may determine an operating parameter and provide wireless power by controlling the first and second PWM drivers (312 and 314, respectively) based on the operating parameter. The PWM drivers (312 and 314, respectively) may operate the first switch 316 and the second switch 318. The first switch 316 and second switch 318 may energize the primary coil 322 in a manner that transmits wireless power according to the operating parameter to a secondary coil of the wireless power reception apparatus.
In accordance with techniques of this disclosure, the TX controller 108 can detect a fault in the wireless power reception apparatus by monitoring the amount of wireless power transferred via the PTx circuit 350. The wireless power transmission apparatus 300 may include a measurement unit 308. The measurement circuit 308 may measure one or more characteristics (such as voltage, current, or both) through the PTx circuit 350. In some implementations, the measurement circuit may be connected to the rectifier (such as either on the power source 302 side as shown in
The receiver controller 424 may receive various information and determine a control error value, a power request value or other feedback to communicate to a wireless power transmission apparatus via the communication unit 432. In
The RX controller 424 also may communicate with a wireless power transmission apparatus via the communication interface 426. In some implementations, the RX controller 424 may obtain configuration data from a memory (not shown). The configuration data may be transmitted by the communication interface 426 to the wireless power transmission apparatus. The RX controller 424 also may obtain information indicating load states and/or power estimates from a load controller (not shown) or user interface (not shown). At various times before, during, or after the transfer of wireless power, the communication interface 426 may transmit, to the wireless power transmission apparatus, the aforementioned configuration data, voltage measurement information, coupling information, power request information, load voltage information, the load state, among other examples. The load setting may be a user-selectable setting, such as a temperature setting, cooking time, or motor speed setting, among other examples. In some implementations, the configuration data may include a rated power value and a time parameter associated with an operation of the load 408. For example, the time parameter may indicate an expected time to boil water, toast bread, or cook food based on the load setting. In some instances, the RX controller 424 may transmit some or all of the configuration data to the transmission controller during a handshaking process, as described herein. In some instances, the RX controller 424 may transmit feedback information to a wireless power transmission apparatus. The feedback information may include one or more of a load state, a reference voltage, a power estimate or request for the load, the coupling factor information, the load voltage information, a fault state (when detected by the example wireless power reception apparatus 400), or any combination thereof. A TX controller (not shown) of the wireless power transmission apparatus may modify the wireless power being transmitted to the wireless power reception apparatus 400 based on the feedback information. The communication interface 426 may be configured to communicate messages to the wireless power transmission apparatus during predetermined communication slots. For example, the communication slots may be determined based on a synchronization unit (not shown), clock, or other device. For example, communication slots may occur at times when there is no switching in the wireless power transmission apparatus and may be determined when the coil sensed voltage (at the secondary coil 402) is zero.
As describe further with reference to
Using the inverter voltage and current information 712 for a power transfer period and the alternating current (AC) frequency of the power source, the TX controller 708 may determine a transmitted power measurement 718. An average power transfer amount 730 (which may be referred to as Pavg) may be calculated as an average of transmitted power measurements associated with the power transfer period. Formula (1a) shows an equation to determine the average power transfer amount.
Where fac is the AC frequency of the power source, Vinv(t) is the instantaneous inverter voltage, Iinv(t) is the instantaneous inverter current and dt represents the integration operation with respect to time and for the power transfer period (such as a half cycle of the AC power supply). The above equation in discrete time domain with a sampling time of ‘Ts’ and containing ‘n’ samples in half AC cycle can be represented as shown in Formula (1b).
The TX controller 708 also may adjust the average power transfer amount 730 by subtracting the expected power transmission loss 728. The expected power transmission loss 728 may be based on transmitter characteristics 722. Formula (2) shows an example calculation for the expected power transmission loss 728 (PlossPTX).
Where Ploss (coil) is the loss associated with the primary coil, Ploss (electronics) is the loss associated with other components of the PTx circuit, and Ploss (ferrites) is the loss in the ferrites in the wireless power transmission apparatus.
The TX controller 708 may determine a fault detection threshold 738. The fault detection threshold may be based on the power transfer amount 730 (such as a factor of the power transfer amount 730) or based on a configurable offset value. At block 750, the TX controller 708 may compare the power transfer amount 730 and the fault detection threshold 738. If the power transfer amount 730 (the average transmitted power adjusted based on the expected power transmission loss 728) is below the fault detection threshold 738, the TX controller 708 may determine that a fault of the wireless power reception apparatus has been detected. Alternatively, if the power transfer amount 730 is not below the fault detection threshold 738, the TX controller 708 may not determine the fault and may continue power transfer phase. Formula (3) shows an example comparison for block 750.
where FDthreshold is the fault detection threshold 738.
In some instances, the TX controller 708 may record multiple instances of the power transfer amount being below the fault detection threshold before determining that the fault has been detected. For example, the fault may be detected after a threshold quantity of power transfer amounts (over successive power transfer periods) are below the fault detection threshold. In some implementations, the TX controller 708 may adjust an operating parameter (such as an operating frequency) after a first instance of the power transfer amount being below the fault detection threshold. If the power transfer amount remains below the fault detection threshold after changing the operating parameter, the TX controller 708 may determine that the fault is detected. A first instance may cause the TX controller 708 to suspect the fault, which may be confirmed by the second (or multiple) instances of the power transfer amount being below the fault detection threshold. In some implementations, the TX controller 708 may adjust the operating parameter over multiple power transfer periods during a power transfer phase. If the power transfer amounts for each of the power transfer periods remain below the fault detection threshold for a fault detection time period, the TX controller 708 may determine that the fault has been detected.
The wireless power transmission apparatus may include a synchronization unit that may provide a signal representing the AC voltage curve 802 or the rectified DC voltage curve 806 to the TX controller 108. Near every point at which the AC mains voltage is zero (also referred to as a zero crossing), the TX controller 108 may stop power transfer for a short time (such as approximately 300 microseconds, approximately one millisecond, or any other suitable time period) by disabling a PWM driver to create time slots for other operations. Other operations may include data communication between the wireless power transmission apparatus and the wireless power reception apparatus using NFC, a K-factor determination process, or foreign object detection (FOD) operations, among other examples. In some implementations, an absence of power transfer to the wireless power transmission apparatus during these instances may serve as a clock to the wireless power reception apparatus to synchronize its operation with the wireless power transmission apparatus. Hence, the wireless power transmission apparatus can synchronously cooperate with the wireless power reception apparatus. In some implementations, the zero cross events illustrated as lines 808 are designated a regularly recurring communication slots during which the wireless power reception apparatus communicates with the wireless power transmission apparatus using an out-of-band channel. The time between communication slots may be referred to as power transfer periods. For example, power transfer periods 810A, 810B, 810C, and 810D are each associated with one half cycle of the AC voltage curve.
In some implementations, the fault detection criterion may be based on a threshold quantity of power transfer periods during which the power transfer amount is below the threshold. In some implementations, the fault detection criterion may be based on a threshold quantity of different operating points that have resulted in a power transfer amount remaining below the fault detection threshold. In yet other implementations, the fault detection criterion may be an expiration of a fault detection time period 970.
Once the fault detection criterion is satisfied, the wireless power transmission apparatus 102 may determine that a fault of the wireless power reception apparatus 118 has been detected. The wireless power transmission apparatus 102 may cease wireless power transmission 980. In some implementations, the wireless power transmission apparatus 102 may present an indication of the fault via a user interface of the wireless power transmission apparatus 102. In some implementations, the wireless power transmission apparatus 102 may transmit a fault detection message 985 to the wireless power reception apparatus 118. The wireless power reception apparatus 118 may present an indication of the fault via a user interface of the wireless power reception apparatus 118.
Where Prated is the power rated value and Trated is the time parameter, both of which may be obtained from the receiver data 1002.
An energy monitoring unit 1040 may determine a total amount of energy transferred to the wireless power reception apparatus based on TX inverter voltage and current information 1032 and power transfer period timer 1034. For example, the energy monitoring unit 1040 may determine average power transfer amounts for each power transfer period using the calculations described with reference to Formula (1a) or Formula (1b). Formula (5) shows an example calculation of the total energy transferred.
Where Pavgi is calculated according to Formula (1a) or Formula (1b) and Ti is a time associated with the power transfer period.
At block 1050, the TX controller 1008 may compare the total amount of energy transferred to the wireless power reception apparatus and the energy requirement (as a limit). If the total energy transferred exceeds the energy requirement and the wireless power transmission apparatus receives an unexpected power control communication (shown at block 1060), the TX controller 1008 may determine that the fault of the wireless power reception apparatus has been detected (shown at block 1070). If the limit is not exceeded, the TX controller 1008 may continue to transmit wireless power and update the total energy transferred amount. In some implementations, a threshold or factor may be used during the comparison of the total amount of energy transferred and the energy requirement. Formula (6) shows an example comparison that includes a hysteresis factor.
The factor may be a multiplier (such as 1.1 or 1.2) to increase the energy requirement by a percentage factor. In some implementations, the factor may be “1” and instead a threshold parameter (not shown) may be added to the energy requirement.
A second scenario describes fault detection when a total power transmission time exceeds a maximum power transmission time calculated by the wireless power transmission apparatus. The energy estimation unit 1020 may determine the maximum power transmission time based on a rated power value in the receiver data 1002 as well as one or more operating parameters of the wireless power transmission apparatus. For example, the one or more operating parameters may include an operating frequency and an operating voltage which the TX controller 1008 intends to use throughout the power transfer phase. The maximum wireless power transmission time may represent how long the wireless power transmission apparatus should transmit wireless power using those operating parameters in order to reach an energy request of the wireless power transmission apparatus. In some implementations, the maximum power transmission time may depend on the receiver volume, the primary coil, electronic thermal limits, or other factors. In some implementations, the maximum power transmission time may be based on other factors, such as a time limit set by the wireless power transmission apparatus manufacturer, a calculation by the TX controller based on the operating thermal or other conditions of the PTx circuit, or a user setting in the wireless power transmission apparatus, among other examples.
The energy monitoring unit 1040 may determine a total transmission time (Ttotal) as a sum of the power transfer periods during which the wireless power transmission apparatus transmits wireless power using the one or more operating parameters. Formula (7) shows an example calculation of the total transmission time (Ttotal).
where k the number of power transfer periods and Ti is the duration of the power transfer periods.
At block 1050, the TX controller 1008 may compare the total transmission time to the maximum wireless power transmission time (as a limit). If the total transmission time exceeds the maximum wireless power transmission time and the wireless power transmission apparatus receives an unexpected power control communication (shown at block 1060), the TX controller 1008 may determine that the fault of the wireless power reception apparatus has been detected (shown at block 1070). If the limit is not exceeded, the TX controller 1008 may continue to transmit wireless power and update the total transmission time.
At block 1110, the apparatus may receive information from a wireless power reception apparatus related to an operation of the wireless power reception apparatus.
At block 1120, the apparatus may determine an energy requirement of the wireless power reception apparatus based, at least in part, on the information.
At block 1130, the apparatus may enter a power transfer phase. During the power transfer phase, the apparatus may perform operations at blocks 1140, 1150, and 1160. At block 1140, the apparatus may periodically receive power control communications from the wireless power reception apparatus. At block 1150, the apparatus may transmit wireless power to the wireless power reception apparatus. At block 1160, the apparatus may detect a fault of the wireless power reception apparatus in response to receiving an unexpected power control communication from the wireless power reception apparatus after a total amount of energy transferred to the wireless power reception apparatus exceeds the energy requirement by a threshold amount.
In some implementations, when the apparatus detects the fault in block 1160, the process 1100 continues to block 1180 where the apparatus exits the power transfer phase. The apparatus may cease transmission of the wireless power. In some implementations, the apparatus may transmit a fault detection message to the wireless power reception apparatus.
At block 1210, the apparatus may receive information from a wireless power reception apparatus related to an operation of the wireless power reception apparatus.
At block 1220, the apparatus may determine a maximum power transmission time based, at least in part, on the information and one or more operating parameters of the wireless power transmission apparatus.
At block 1230, the apparatus may enter a power transfer phase. During the power transfer phase, the apparatus may perform operations at blocks 1240, 1250, and 1260. At block 1240, the apparatus may periodically receive power control communications from the wireless power reception apparatus. At block 1250, the apparatus may transmit wireless power to the wireless power reception apparatus using the one or more operating parameters. At block 1260, the apparatus may detect a fault of the wireless power reception apparatus in response to receiving an unexpected power control communication from the wireless power reception apparatus after a total power transmission time exceeds the maximum power transmission time.
In some implementations, when the apparatus detects the fault in block 1260, the process 1200 continues to block 1280 where the apparatus exits the power transfer phase. The apparatus may cease transmission of the wireless power. In some implementations, the apparatus may transmit a fault detection message to the wireless power reception apparatus.
The apparatus 1300 may include one or more controller(s) 1362 configured to manage multiple primary or secondary coils (such as a coil array 1364). In some implementations, the controller(s) 1362 can be distributed within the processor 1302, the memory 1306, and the bus 1311. The controller(s) 1362 may perform some or all of the operations described herein. For example, the controller(s) 1362 may be a transmission controller, such as any of the transmission controllers described herein.
The memory 1306 can include computer instructions executable by the processor 1302 to implement the functionality of the implementations described with reference to
The foregoing disclosure provides illustration and description but is not intended to be exhaustive or to limit the aspects to the precise form disclosed. Modifications and variations may be made in light of the above disclosure or may be acquired from practice of the aspects. While the aspects of the disclosure have been described in terms of various examples, any combination of aspects from any of the examples is also within the scope of the disclosure. The examples in this disclosure are provided for pedagogical purposes. Alternatively, or in addition to the other examples described herein, examples include any combination of the following implementation options (identified as clauses for reference).
Clause 1. A method performed by a wireless power transmission apparatus, including: receiving information from a wireless power reception apparatus related to an operation of the wireless power reception apparatus: determining an energy requirement of the wireless power reception apparatus based on the information: and during a power transfer phase: periodically receiving power control communications from the wireless power reception apparatus: transmitting wireless power to the wireless power reception apparatus: and detecting, by the wireless power transmission apparatus, a fault of the wireless power reception apparatus in response to receiving an unexpected power control communication from the wireless power reception apparatus after a total amount of energy transferred to the wireless power reception apparatus exceeds the energy requirement by a threshold amount.
Clause 2. The method of clause 1, wherein receiving information from the wireless power reception apparatus includes receiving a rated power value and a time parameter indicating an expected time for the wireless power reception apparatus to complete the operation based on the rated power value.
Clause 3. The method of clause 2, wherein determining the energy requirement includes multiplying the rated power value and the time parameter to determine the energy requirement.
Clause 4. The method of any one of clauses 1-3, wherein the energy requirement represents a total amount of energy required by the wireless power reception apparatus to complete the operation.
Clause 5. The method of any one of clauses 1-4, further including: periodically determining the total amount of energy transferred to the wireless power reception apparatus during the power transfer phase.
Clause 6. The method of clause 5, wherein determining the total amount of energy transferred includes: determining a plurality of power transfer amounts corresponding to a plurality of power transfer periods based on measurements at the wireless power transmission apparatus: and calculating the total amount of energy transferred based on a sum of each of the plurality of power transfer amounts multiplied by a corresponding one of the plurality of power transfer periods.
Clause 7. The method of clause 6, wherein determining the plurality of power transfer amounts includes, for each power transfer amount of the plurality of power transfer amounts: measuring a voltage and a current associated with an inverter coupled to the primary coil during a corresponding power transfer period: calculating an input power based on the voltage and the current during the corresponding power transfer period: and determining the power transfer amount based on a difference between the input power and an expected power transmission loss associated with the wireless power transmission apparatus.
Clause 8. The method of clause 7, wherein one or more power transfer periods are consecutive time periods and each of the one or more power transfer periods includes one or more half cycles of an alternating current (AC) power supply coupled to the inverter.
Clause 9. The method of any one of clauses 1-8, further including: detecting the fault of the wireless power reception apparatus regardless of whether the wireless power transmission apparatus continues to receive messages from the wireless power reception apparatus.
Clause 10. The method of any one of clauses 1-9, further including ceasing transmission of power in response to detecting the fault.
Clause 11. The method of any one of clauses 1-10, further including communicating a fault detection message to the wireless power reception apparatus in response to detecting the fault.
Clause 12. The method of any one of clauses 1-11, further including determining the threshold amount based on the energy requirement multiplied by a factor variable.
Clause 13. The method of any one of clauses 1-12, further including determining the threshold amount based on a configurable offset value.
Clause 14. A wireless power transmission apparatus, including: a communication unit configured to receive information from a wireless power reception apparatus related to an operation of the wireless power reception apparatus: a primary coil configured to transmit wireless power to the wireless power reception apparatus during a power transfer phase: the communication unit configured to periodically receive power control communications from the wireless power reception apparatus during the power transfer phase: and a transmission controller configured to: determine an energy requirement of the wireless power reception apparatus based on the information: and detect a fault of the wireless power reception apparatus in response to receiving an unexpected power control communication from the wireless power reception apparatus after a total amount of energy transferred to the wireless power reception apparatus exceeds the energy requirement by a threshold amount.
Clause 15. The wireless power transmission apparatus of clause 14, wherein the information received from the wireless power reception apparatus includes a rated power value and a time parameter indicating an expected time for the wireless power reception apparatus to complete the operation based on the rated power value.
Clause 16. The wireless power transmission apparatus of clause 15, wherein the transmission controller is configured to determine the energy requirement by multiplying the rated power value and the time parameter to determine the energy requirement.
Clause 17. The wireless power transmission apparatus of any one of clauses 14-16, wherein the energy requirement represents a total amount of energy required by the wireless power reception apparatus to complete the operation.
Clause 18. The wireless power transmission apparatus of any one of clauses 14-17, wherein the transmission controller is configured to periodically determine the total amount of energy transferred to the wireless power reception apparatus during the power transfer phase.
Clause 19. The wireless power transmission apparatus of clause 18, wherein the transmission controller is configured to determine the total amount of energy transferred by operations that include: determining a plurality of power transfer amounts corresponding to a plurality of power transfer periods based on measurements at the wireless power transmission apparatus: and calculating the total amount of energy transferred based on a sum of each of the plurality of power transfer amounts multiplied by a corresponding one of the plurality of power transfer periods.
Clause 20. The wireless power transmission apparatus of clause 19, further including: a power signal generator configured to generate power for transmission via the primary coil, the power signal generating including an inverter: and a voltage sensor and a current sensor coupled to the inverter and configured to measure a voltage and a current, respectively, associated with the inverter, wherein the transmission controller is configured to, for each power transfer period of the one or more power transfer periods: calculate an input power based on the voltage and the current during a corresponding power transfer period: and determine a power transfer amount associated with the power transfer period based on a difference between the input power and an expected power transmission loss associated with the wireless power transmission apparatus.
Clause 21. The wireless power transmission apparatus of clause 20, wherein one or more power transfer periods are consecutive time periods and each of the one or more power transfer periods includes one or more half cycles of an alternating current (AC) power supply coupled to the inverter.
Clause 22. The wireless power transmission apparatus of any one of clauses 14-21, wherein the transmission controller is configured to detect the fault of the wireless power reception apparatus regardless of whether the unexpected power control communication indicates that the wireless power reception apparatus is receiving the wireless power.
Clause 23. The wireless power transmission apparatus of any one of clauses 14-22, wherein the transmission controller is configured to cause the wireless power transmission apparatus to cease transmission of power to the wireless power reception apparatus in response to detecting the fault.
Clause 24. The wireless power transmission apparatus of any one of clauses 14-23, further including: the communication unit configured to communicate a fault detection message to the wireless power reception apparatus in response to the transmission controller detecting the fault.
Clause 25. The wireless power transmission apparatus of any one of clauses 14-24, wherein the transmission controller is configured to determine the threshold amount based on the energy requirement multiplied by a factor variable.
Clause 26. The wireless power transmission apparatus of any one of clauses 14-25, wherein the transmission controller is configured to determine the threshold amount based on a configurable offset value.
Clause 27. A method performed by a wireless power transmission apparatus, including: receiving information from a wireless power reception apparatus related to an operation of the wireless power reception apparatus: determining a maximum power transmission time based on the information and one or more operating parameters of the wireless power transmission apparatus: and during a power transfer phase: periodically receiving power control communications from the wireless power reception apparatus: transmitting wireless power to the wireless power reception apparatus using the one or more operating parameters: and detecting, by the wireless power transmission apparatus, a fault of the wireless power reception apparatus in response to receiving an unexpected power control communication from the wireless power reception apparatus after a total power transmission time exceeds the maximum power transmission time.
Clause 28. The method of clause 27, wherein receiving information from the wireless power reception apparatus includes receiving a rated power value and a time parameter indicating an expected time for the wireless power reception apparatus to complete the operation based on the rated power value.
Clause 29. The method of clause 28, wherein determining the maximum power transmission time includes determining the maximum power transmission time based on the time parameter.
Clause 30. The method of any one of clauses 27-29, wherein determining the maximum power transmission time includes: determining a power transfer amount expected per power transfer period based on the one or more operating parameters: and determining the maximum power transmission time based on a rated power of the wireless power reception apparatus and the power transfer amount expected per power transfer period.
Clause 31. The method of clause 30, wherein the one or more operating parameters include an operating voltage, an operating frequency, an operating duty, and a coupling factor of a primary coil of the wireless power transmission apparatus during the power transfer phase.
Clause 32. The method of any one of clauses 27-31, wherein the maximum power transmission time is further based on electronic thermal limits of the wireless power transmission apparatus or the wireless power reception apparatus.
Clause 33. The method of any one of clauses 27-32, further including: periodically determining the total power transmission time during the power transfer phase.
Clause 34. The method of clause 33, wherein determining the total power transmission time includes: determining the total power transmission time as a sum of a plurality of power transfer periods during which the wireless power transmission apparatus transmits wireless power to the wireless power reception apparatus using the one or more operating parameters.
Clause 35. The method of any one of clauses 27-34, further including: detecting the fault of the wireless power reception apparatus regardless of whether the unexpected power control communication indicates that the wireless power reception apparatus is receiving the wireless power.
Clause 36. The method of any one of clauses 27-35, further including ceasing transmission of power in response to detecting the fault.
Clause 37. The method of any one of clauses 27-36, further including communicating a fault detection message to the wireless power reception apparatus in response to detecting the fault.
Clause 38. A wireless power transmission apparatus, including: a communication unit configured to receive information from a wireless power reception apparatus related to an operation of the wireless power reception apparatus: a primary coil configured to transmit wireless power to the wireless power reception apparatus using one or more operating parameters of the wireless power transmission apparatus during a power transfer phase: the communication unit configured to periodically receive power control communications from the wireless power reception apparatus during the power transfer phase: and a transmission controller configured to: determine maximum power transmission time based on the information and the one or more operating parameters: and detect a fault of the wireless power reception apparatus in response to receiving an unexpected power control communication from the wireless power reception apparatus after a total power transmission time exceeds the maximum power transmission time.
Clause 39. The wireless power transmission apparatus of clause 38, wherein the information received from the wireless power reception apparatus includes a rated power value and a time parameter indicating an expected time for the wireless power reception apparatus to complete the operation based on the rated power value.
Clause 40. The wireless power transmission apparatus of clause 39, wherein the transmission controller is configured to determine the maximum power transmission time includes determining the maximum power transmission time based on the time parameter.
Clause 41. The wireless power transmission apparatus of any one of clauses 38-40, wherein the transmission controller is configured to: determine a power transfer amount expected per power transfer period based on the one or more operating parameters: and determine the maximum power transmission time based on a rated power of the wireless power reception apparatus and the power transfer amount expected per power transfer period.
Clause 42. The wireless power transmission apparatus of clause 41, wherein the one or more operating parameters include an operating voltage, an operating frequency, an operating duty and a coupling factor of a primary coil of the wireless power transmission apparatus during the power transfer phase.
Clause 43. The wireless power transmission apparatus of any one of clauses 38-42, wherein the maximum power transmission time is further based on component thermal limits of the wireless power transmission apparatus or the wireless power reception apparatus.
Clause 44. The wireless power transmission apparatus of any one of clauses 38-43, wherein the transmission controller is configured to periodically determine the total power transmission time during the power transfer phase.
Clause 45. The wireless power transmission apparatus of clause 44, wherein the transmission controller is configured to determine the total power transmission time as a sum of a plurality of power transfer periods during which the wireless power transmission apparatus transmits wireless power to the wireless power reception apparatus using the one or more operating parameters.
Clause 46. The wireless power transmission apparatus of any one of clauses 38-45, wherein the transmission controller is configured to detect the fault of the wireless power reception apparatus regardless of whether the unexpected power control communication indicates that the wireless power reception apparatus is receiving the wireless power.
Clause 47. The wireless power transmission apparatus of any one of clauses 38-46, wherein the transmission controller is configured to cause the wireless power transmission apparatus to cease transmission of power to the wireless power reception apparatus in response to detecting the fault.
Clause 48. The wireless power transmission apparatus of any one of clauses 38-47, further including: the communication unit configured to communicate a fault detection message to the wireless power reception apparatus in response to the transmission controller detecting the fault.
Another innovative aspect of the subject matter described in this disclosure can be implemented as a computer-readable medium having stored therein instructions which, when executed by a processor, causes the processor to perform any one of the above-mentioned functionalities.
Another innovative aspect of the subject matter described in this disclosure can be implemented as a system having means for implementing any one of the above-mentioned functionalities.
Another innovative aspect of the subject matter described in this disclosure can be implemented as an apparatus having one or more processors configured to perform one or more operations from any one of the above-mentioned methods.
As used herein, a phrase referring to “at least one of” or “one or more of”' a list of items refers to any combination of those items, including single members. For example, “at least one of: a, b, or c” is intended to cover the possibilities of: a only, b only, c only, a combination of a and b, a combination of a and c, a combination of b and c, and a combination of a and b and c.
The various illustrative components, logic, logical blocks, modules, circuits, operations and algorithm processes described in connection with the implementations disclosed herein may be implemented as electronic hardware, firmware, software, or combinations of hardware, firmware or software, including the structures disclosed in this specification and the structural equivalents thereof. The interchangeability of hardware, firmware and software has been described generally, in terms of functionality, and illustrated in the various illustrative components, blocks, modules, circuits and processes described above. Whether such functionality is implemented in hardware, firmware or software depends upon the particular application and design constraints imposed on the overall system.
The hardware and data processing apparatus used to implement the various illustrative components, logics, logical blocks, modules and circuits described in connection with the aspects disclosed herein may be implemented or performed with a general purpose single-or multi-chip processor, a digital signal processor (DSP), an application specific integrated circuit (ASIC), a field programmable gate array (FPGA) or other programmable logic device (PLD), discrete gate or transistor logic, discrete hardware components, or any combination thereof designed to perform the functions described herein. A general-purpose processor may be a microprocessor, or, any conventional processor, controller, microcontroller, or state machine. A processor also may be implemented as a combination of computing devices, for example, a combination of a DSP and a microprocessor, multiple microprocessors, one or more microprocessors in conjunction with a DSP core, or any other such configuration. In some implementations, particular processes, operations and methods may be performed by circuitry that is specific to a given function.
As described above, in some aspects of the subject matter described in this specification can be implemented as software. For example, various functions of components disclosed herein, or various blocks or steps of a method, operation, process or algorithm disclosed herein can be implemented as one or more modules of one or more computer programs. Such computer programs can include non-transitory processor-executable or computer-executable instructions encoded on one or more tangible processor-readable or computer-readable storage media for execution by, or to control the operation of, a data processing apparatus including the components of the devices described herein. By way of example, and not limitation, such storage media may include RAM, ROM, EEPROM, CD-ROM or other optical disk storage, magnetic disk storage or other magnetic storage devices, or any other medium that may be used to store program code in the form of instructions or data structures. Combinations of the above should also be included within the scope of storage media.
Various modifications to the implementations described in this disclosure may be readily apparent to persons having ordinary skill in the art, and the generic principles defined herein may be applied to other implementations without departing from the scope of this disclosure. Thus, the claims are not intended to be limited to the implementations shown herein but are to be accorded the widest scope consistent with this disclosure, the principles and the novel features disclosed herein.
Additionally, various features that are described in this specification in the context of separate implementations also can be implemented in combination in a single implementation. Conversely, various features that are described in the context of a single implementation also can be implemented in multiple implementations separately or in any suitable subcombination. As such, although features may be described above as acting in particular combinations, and even initially claimed as such, one or more features from a claimed combination can in some cases be excised from the combination, and the claimed combination may be directed to a subcombination or variation of a subcombination.
Similarly, while operations are depicted in the drawings in a particular order, this should not be understood as requiring that such operations be performed in the particular order shown or in sequential order, or that all illustrated operations be performed. to achieve desirable results. Further, the drawings may schematically depict one or more example processes in the form of a flowchart or flow diagram. However, other operations that are not depicted can be incorporated in the example processes that are schematically illustrated. For example, one or more additional operations can be performed before, after, simultaneously, or between any of the illustrated operations. In some circumstances, multitasking and parallel processing may be advantageous. Moreover, the separation of various system components in the implementations described above should not be understood as requiring such separation in all implementations, and it should be understood that the described program components and systems can generally be integrated together in a single software product or packaged into multiple software products.
This application claims priority benefit of United States Provisional Application No. 63/242, 102 filed Sep. 9, 2021, entitled “Fault Detection in Wireless Power System” and assigned to the assignee hereof. The disclosure of the aforementioned application is considered part of and are incorporated by reference in this Patent Application.
Filing Document | Filing Date | Country | Kind |
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PCT/US2022/042957 | 9/8/2022 | WO |
Number | Date | Country | |
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63242102 | Sep 2021 | US |