KR20170097624A - Apparatus and methods to provide a selectable charging voltage - Google Patents

Abstract

In an embodiment, the apparatus includes detector logic having a first resonant frequency. The detector logic receives a power management signal having a power management signal frequency and provides an indication of whether the power management signal frequency is within a first frequency differential of the first resonant frequency. The apparatus also includes means for causing the power adapter circuitry to change the output voltage from a first voltage to a second voltage that is separate from the first voltage in response to an indication that the management signal frequency is within a first frequency difference of the first resonant frequency And the switch signal logic for activating the first switching signal to enable the first switching signal. Other embodiments are described and claimed.

Description

[0001] APPARATUS AND METHODS TO PROVIDE A SELECTABLE CHARGING VOLTAGE [0002]

The field is power transmission.

Portable devices (PD), such as tablet computers and mobile phones, may use a micro-universal serial bus (USB) port or a Type-C USB port for data transfer as well as charging have. For example, charging through micro-USB or Type-C USB ports may be done at 5 V, 1.5 A (e.g., 7.5 W) and may require a long time to charge. Also, if the device is active during charging, the charging time may be longer than when the device is not active during charging.

1 is a block diagram of an apparatus according to embodiments of the present invention.
2 is a block diagram of an apparatus according to another embodiment of the present invention.
3 is a flow chart of a method according to an embodiment of the present invention.
4 is a flow diagram of a method according to another embodiment of the present invention.

In embodiments, an alternating current (AC) power adapter may be used at a selectable rate, e.g., a standard (also referred to herein as a "normal") rate (eg, 5 V, 1.5 ampere) And a detection device that may enable charging of the portable device by a power source at a rate higher than the standard rate. Embodiments may enable charging at a rate that is higher than the standard rate, with a relatively low cost implementation and without adding an integrated circuit in the AC power adapter.

In embodiments, the USB-only charging AC adapter may use a portable device handshake and may result in a faster charging of the portable device through the USB port, from a first voltage level, e.g., 5V, (E.g., 12 V) at a second voltage level (e.g., 12 V). Detection of a compatible portable device by an AC adapter may be realized through an inductor-capacitor (L-C) tank circuit that resonates at a defined frequency. The use of an L-C tank circuit for identification of a compatible portable device may be implemented at a lower cost than, for example, the use of a dedicated integrated circuit (IC) in an AC adapter to identify a compatible portable device. In some embodiments, multiple L-C tank circuits may be employed to enable charging at any of a plurality of voltage levels, for example, without affecting USB communication. Charging at higher voltage levels may be possible whether the portable system is in shut down mode or active mode. The use of one or more L-C tank circuits may be compatible, for example, with USB BC1.2 and USB power delivery (PD) features.

1 is a block diagram of an apparatus 100 according to an embodiment of the present invention. The apparatus 100 includes a USB AC adapter 110 and a portable device 150 that includes power management logic 120 and a system on a chip (SOC) The USB AC adapter 110 is for connecting to the portable device 150 via the USB connector 140.

The USB AC adapter 110 includes an AC / DC converter 112 and a detector 114. In portable device 150, power management logic 120 includes USB charger interface 122, status / configuration registers 124, USB switches 126, signal generator logic 152, ammeter 154 (e.g., , Current measurement logic), and a USB port 140. USB port 140 may be, for example, a Micro-AB port, a Type-C port, or another USB port.

In an embodiment, a change in charge voltage from a first charge voltage through the USB port 140 to a second (e.g., higher) charge voltage may occur as follows. (In other embodiments, the order in which actions are executed may vary.)

The USB adapter 110 may be coupled to an AC source 102. When the USB adapter 110 is coupled to the AC source 102, the USB adapter 110 may drive the first voltage (e.g., 5 V) to the USB port 140. [ Optionally, the power conduit VBUS 122 may be configured to detect an upstream facing port (UFP) pull down on the CC pin of the USB adapter 110 (e.g., (Detected in the memory 142). In some embodiments, the USB adapter 110 behaves like a BC1.2 DCP adapter and conforms to the BC1.2 DCP adapter specification.

The portable device 150 may detect that the USB adapter 110 is a dedicated charger. For USB Type B or Type AB, D + / D- lines 118/119 may be available for voltage negotiation. When a Type-C USB port such as the USB port 160 is used, one of D +, D-, CC, SBU1, SBU2, RX1 +, RX1-, RX2 +, RX2-, TX1 +, TX1-, TX2 +, or TX2- May be available for voltage negotiation. The portable device 150 begins to charge at the normal charging voltage. In some embodiments, the normal charge voltage is approximately 5 volts.

The signal generator logic 152 may generate a signal (e.g., a square wave signal) and transmit the signal through a charger interface 122 to a line available at a signal frequency that may be incremented within a defined frequency band. (Either any of D + 118 or D-lines 119, for Type B or Type AB, any available line from the above listed lines for Type-C) . The signal may be communicated to the USB adapter 110. The signal frequency may start from a minimum frequency, and the frequency may be incremented by an incremental step (e.g., frequency sweep or frequency drive in this application).

The portable device 150 may also detect a resonant load during a frequency sweep, for example, through a change in the current supplied by the signal generator logic 152, as detected by the ammeter 154 . The portable device 150 may be capable of fine tuning and locking the signal frequency at or near the resonant frequency of the tank circuit located within the detector 114 of the USB adapter. If no resonant load is found, the portable device 150 will continue normal charging at, for example, the normal charging voltage.

In some embodiments, at a signal frequency that is within a frequency band that may include, for example, the resonant frequency of the tank circuit, exceeds the resonant frequency by a frequency differential, and may extend below the resonant frequency, At resonance, or in proximity to resonance, the LC tank circuit voltage at the USB AC adapter 110 may increase to multiples of the drive voltage (e.g., from 3.3 V, increasing by more than 5 V) . This increase in voltage may occur at or near the resonant frequency of the tank circuit. The increased voltage may be used, for example, to activate a field effect transistor (FET) in the detector 114 to change the AC adapter output voltage. The higher voltage at resonance may act as an indicator that the charge voltage may change (e.g., to a higher output voltage). The resonance and the resulting higher resonant circuit voltage may be the same or different, which is not easily confused by other communication waveforms.

Separate resonant frequencies may be assigned to each of the plurality of high voltage levels, and each of the plurality of high voltage levels may have a corresponding L-C tank circuit within the detector 114. In some embodiments, the AC USB adapter 110 may support multiple output voltage levels.

The portable device 150 may check for a desired output voltage (e.g., a higher charging voltage) from the AC adapter 110 on the VBUS 122/142. Charging of the portable device 150 at a higher rate is enabled when the desired output voltage is available from the AC adapter 110 via the USB port 140 prior to expiration of the blank time interval . If the desired output voltage is not available prior to the expiration of the blank time interval, the portable device 150 may stop the frequency sweep and continue normal charging, e.g., at a normal charging voltage. In one embodiment, the normal charge voltage is approximately 5 volts.

When the USB AC adapter 110 is unplugged from the portable device 150, the adapter output voltage is a regular voltage (e.g., 5 V) because the signal is disconnected from the USB AC adapter 110. [ . ≪ / RTI > There may be a time out delay before the charge voltage is reduced to the initial voltage. In some embodiments, the timeout delay is the shortest actual time needed to remove the connector (e.g., USB connector 140) from one device and plug it into another device compatible with the BC1.2 specification May be shorter.

When the USB AC adapter 110 is disconnected, the portable device 150 may disconnect the signal (e.g., a square wave signal) and the normal port function may be resumed.

2 is a block diagram of a USB AC adapter 200 according to another embodiment of the present invention. The USB AC adapter 200 may include an AC / DC converter 210 and a detector 220. Also, lines D + 232, D- 234, VBUS 236, and CC 238 are shown. (In other embodiments, for example, for use with a Type-C USB port, the available lines from the Type-C USB port may be used in voltage negotiation.)

In operation, the USB AC adapter 200 is equipped to be coupled to a portable device (not shown) via a USB plug 240, such as an AB USB port, or a micro / type-C plug, . (E.g., a square wave signal) is detected either through one of the lines D + 232, D- 234, or at the time of detection of the USB AC adapter 200 by the portable device (via the USB plug 240) (E.g., from a portable device) at detector 220 via another available line (e.g., for Type-C USB ports). The received _signal may have a frequency f _signal that varies with time, e.g., sweeps within a determined frequency band (e.g., sweeps from the lowest frequency to the highest frequency of the frequency band).

The LC tank circuit 222 in the detector 220 may "see " the signal. The LC tank circuit 222 may be tuned to a resonant frequency f determined by, for example, the values of the inductor L and the capacitor C. As the varying frequency f _signal approaches the resonant frequency f , the voltage across the LC tank circuit 222 may rise and as the frequency f _signal changes from values farther from the resonant frequency f , the LC tank circuit 222) may drop to a normal value. The portable device can detect the resonance in the LC tank circuit 222 by measuring the current output from the signal generator logic (e.g., within the portable device 150), and when resonance is detected, the signal in the portable device 150 the band to the determined frequency difference includes a frequency exceeding the frequency of the resonant frequency is less than f and the frequency f - generator logic may revert to a frequency range which was the resonance is detected, (e.g., the determined frequency difference between the resonance frequency f (Within) the resonant frequency f , or near the resonant frequency f . Capacitor (RC) circuitry 226 may be configured such that the voltage at resonance frequency f is less than the minimum RC time constant < RTI ID = 0.0 > but also for a time constant. Upon activation of the FET 228, the AC / DC logic 210 may switch from a first charging voltage to a second charging voltage, e.g., the second charging voltage may be higher than the first charging voltage. The charging voltage may be provided to the portable device via the VBUS 236. [

Other embodiments may include a plurality of LC tank circuits in which each LC tank circuit is tuned to a corresponding resonant frequency. Each resonant frequency may be associated with a separate charging voltage that should be provided by the AC / DC logic 210, and a particular charging voltage may be associated with the desired charging voltage (e. G., Provided by the portable device) Lt; / RTI > to a frequency value f _{signal that} is substantially equal (or close to) the corresponding resonant frequency of the LC tank circuit that is being energized.

3 is a flowchart 300 of a method according to an embodiment of the present invention. If, at decision diamond 302, the portable device detects that the USB port VBUS (e.g., charging line) of the USB port is valid, continue to block 304 and the detection is detected by the portable device ≪ / RTI > If decision diamond 306 is not reached and a dedicated charger is not detected, then block 308 is taken and normal portable device functions continue for the portable device PD coupled to the fixed output voltage charger. When a dedicated (e.g., multi-level voltage) charger is detected, the process moves to block 310 where a signal (e.g., a square wave signal) is applied to the free pin of the USB port. The signal has an associated frequency that may be swept through the frequency band. For example, the sweep may be from the minimum frequency of the frequency band to the maximum frequency of the frequency band.

Proceeding to decision diamond 312, continue to block 314, where the resonance is not detected by the portable device (e.g., resonance associated with USB AC adapter circuitry, which may be detected via current measurement logic) Is stopped, and charging at the standard charging voltage is continued. At decision diamond 312, if resonance is detected at the portable device (e.g., by measurement of the current provided by the signal generator logic), continue to block 316, the frequency sweep is stopped and the frequency of the signal is, for example, , Within a frequency band that includes frequencies higher than the resonance frequency and lower than the resonance frequency, at or near the resonance frequency. For example, the frequency band may include frequencies within a defined frequency difference of the resonance frequency.

Proceeding to block 318 to proceed to decision diamond 320 if VBUS does not provide the desired charging voltage to the portable device, and if the blank time interval has not expired, (The charging voltage may expire some time before switching). If the blank time interval expires and the desired charging voltage is not provided via VBUS, proceed to block 314 where the signal is stopped and charging at the normal charging voltage continues.

At decision diamond 318, if VBUS is supplying the desired charging voltage, continuing to block 322 allows charging at the desired rate (e.g., a rate faster than the normal rate). Advancing to decision diamond 324, VBUS is monitored to ensure that the desired charging voltage is provided through VBUS. If the desired charging voltage is not being provided, the process proceeds to block 326 where the signal is stopped, charging is stopped, an interrupt is generated, and an error has occurred, (SOC).

4 is a flow diagram of a method 400 in accordance with another embodiment of the present invention. At decision diamond 402, if the USB AC adapter is plugged into AC power, continue to block 404, where the USB AC adapter converts the standard (e.g., normal) voltage (e.g., 5V) To VBUS, which is an output bus line for transferring data to a USB port coupled to the USB port. And proceeds to decision diamond 406 where the USB AC adapter determines the resonant frequency of the signal, the resonant frequency corresponding to the resonant tank circuit of the USB AC adapter, the USB pin selected by the portable device (e.g., D +, D-, (E.g., a square wave signal), the decision diamond 408 is reached and if the blank time interval expires, the process proceeds to block 410 where the desired charge voltage (e.g., High charge voltage) is enabled on VBUS. If the blank time has not yet expired, return to decision diamond 408 and, when the blank time has expired, go to block 410 and the desired charge voltage is enabled on VBUS.

(E.g., the frequency of which is at the resonant frequency or near the resonant frequency and the signal received at the USB AC charger from the portable device) is transferred to the selected diamond pin 412 that the handheld device has signaled The desired charging voltage (e.g., a high voltage) will continue to be supplied by the USB AC adapter via VBUS as long as it is detected on the VBUS. If the resonant frequency (or a signal whose frequency is close to the resonant frequency) is not detected on the selected USB pin, proceed to decision diamond 414, and if the blank time interval has not expired, return to decision diamond 412, The USB AC adapter continues to determine whether the resonant frequency is on the selected pin. If the blank time interval expires, return to block 404 where the standard voltage is again provided via VBUS for charging the portable device.

Additional embodiments are described below.

In a first embodiment, the apparatus comprises detector logic having a first resonant frequency. The detector logic is for receiving a power management signal having a power management signal frequency and for providing an indication of whether the power management signal frequency is within a first frequency difference of the first resonance frequency. The device is adapted to cause the power adapter circuitry to change the output voltage from a first voltage to a second voltage that is separate from the first voltage in response to an indication that the power management signal frequency is within a first frequency difference of the first resonant frequency Lt; RTI ID = 0.0 > switch < / RTI > signal logic to activate the first switching signal.

The second embodiment includes the components of the first embodiment and includes a circuit for inputting an alternating current (AC) and for outputting a direct current (DC) at a selected output voltage from a plurality of selectable output voltages Power adapter circuitry. In response to receiving the first switching signal, the power adapter circuit portion is for changing the output voltage from the first voltage to the second voltage.

The third embodiment includes the components of the second embodiment. Additionally, the power adapter circuitry is for providing the output voltage to a universal serial bus (USB) connector.

The fourth embodiment includes the components of the third embodiment, and further includes a USB connector.

The fifth embodiment includes the components of the first embodiment. Additionally, in response to a change in the power management signal frequency from a first frequency within a first difference frequency of the resonance frequency to a second frequency outside of a first frequency difference of the resonance frequency, To deactivate the signal. Upon detection of the first switching signal, the output voltage is for changing from the second voltage to the first voltage.

The sixth embodiment includes the components of the first embodiment, wherein the second voltage is greater than the first voltage.

The seventh embodiment includes the components of the sixth embodiment, wherein the first voltage is approximately 5 volts and the second voltage is approximately 12 volts.

The eighth embodiment includes the elements of the first embodiment wherein the detector logic has a second resonant frequency and the detector logic indicates an indication of whether the power management signal frequency is within a second frequency difference of the second resonant frequency In response to an indication that the management signal frequency is within a second frequency difference of the second resonant frequency, the switch signal logic causes the power adapter circuitry to provide the power adapter circuit with a separate, 3 voltage to output the second switching signal.

The ninth embodiment includes the components of the first embodiment, wherein upon recognition of the indication that the power management signal frequency is within the first frequency difference of the first resonant frequency, the switch signal logic causes the detector logic to < So as to cause the power adapter circuitry to change the output voltage from the first voltage to the second voltage after expiration of the blank time interval that begins when it becomes possible to detect.

The tenth embodiment includes the components of the first embodiment, wherein the detector logic includes a resonant circuit portion having a resonant frequency that is a first resonant frequency.

The eleventh embodiment includes the components of the tenth embodiment, wherein the resonant circuit portion includes an inductor-capacitor (L-C) tank circuit.

The twelfth embodiment includes the steps of receiving at the detector logic a power management signal having a power management signal frequency, determining whether the power management signal frequency is within a first frequency difference of the first resonant frequency, In response to the frequency being within a first frequency difference of the first resonant frequency, to cause the output voltage of the power circuit portion to be switched from a first output voltage to a second output voltage that is separate from the first output voltage And providing an indication.

The thirteenth embodiment includes the components of the twelfth embodiment, wherein after the output voltage of the power logic is switched to the second output voltage, the power management signal frequency is shifted to the second In response to varying the power management signal frequency, providing a second indication that the output voltage of the power circuit portion is to be switched to the first output voltage.

The fourteenth embodiment includes the components of the twelfth embodiment, wherein when the power management signal frequency is within a first frequency difference of the first resonant frequency, the output voltage of the power circuit portion is at a first To be switched from the output voltage to the second output voltage.

The fifteenth embodiment includes the components of the twelfth embodiment, wherein the second output voltage is higher than the first output voltage.

The sixteenth embodiment includes the components of the twelfth embodiment, and includes the steps of determining whether the power management signal frequency is within a second frequency difference of the second resonant frequency, and determining whether the power management signal frequency is within a second frequency difference of the second resonant frequency, In response to being in the frequency difference, to cause the output voltage of the power circuit portion to change to a third output voltage that is separate from the first output voltage and the second output voltage.

The seventeenth embodiment is an apparatus for performing the method of any one of embodiments 12-16.

An eighteenth embodiment is an apparatus comprising means for performing the method of any one of embodiments 12-16.

The nineteenth embodiment includes instructions that when executed by a processor cause a processor to receive a power management signal having a power management signal frequency in the power management logic and to cause the power management signal frequency to be within a first frequency difference of the first resonance frequency And in response to the power management signal frequency being within a first frequency difference of the first resonant frequency, outputting the output voltage of the power circuit portion from a first output voltage to a second output Readable < / RTI > medium that stores processor executable instructions to cause a computer to switch to a voltage.

The twentieth embodiment includes the components of the nineteenth embodiment, wherein after the output voltage of the power logic is switched to the second output voltage, the power management signal frequency is shifted to the second Further comprising instructions for switching the output voltage of the power circuit portion to a first output voltage in response to having the power management signal frequency.

The twenty-first embodiment includes the components of the nineteenth embodiment, wherein when the power management signal frequency is within the first frequency difference of the first resonance frequency, the output voltage of the power circuit portion is switched to the blank time interval Wherein the blank time interval begins at an initial time of the determination that the power management signal frequency is within a first frequency difference of the first resonance frequency.

The twenty-second embodiment includes the components of the nineteenth embodiment, and determines whether the power management signal frequency is within a second frequency difference of the second resonant frequency, and if the power management signal frequency is greater than or equal to a second frequency of the second resonant frequency Instructions for changing the output voltage of the power circuit portion to a third output voltage that is different from the first output voltage and the second output voltage in response to being in the differential.

The thirtieth embodiment includes a means for receiving a power management signal having a power management signal frequency, means for determining whether the power management signal frequency is within a first frequency difference of the first resonant frequency, In response to being in the first frequency difference of the first resonant frequency, to cause the output voltage of the power circuit portion to switch from the first output voltage to a second output voltage that is separate from the first output voltage And a means for providing the device.

The twenty-fourth embodiment includes the components of the twenty-third embodiment, wherein after the output voltage of the power logic is switched to the second output voltage, the power management signal frequency is shifted to the second And means for providing a second indication that, in response to changing to the power management signal frequency, the output voltage of the power circuit portion is switched to the first output voltage.

The twenty-fifth embodiment includes the components of the twenty-third embodiment, wherein when the power management signal frequency is within the first frequency difference of the first resonance frequency, the output voltage of the power circuit portion at the expiration of the blank time interval is divided into a first output voltage To a second output voltage.

The twenty-sixth embodiment includes the components of the twenty-third embodiment, wherein the second output voltage is higher than the first output voltage.

The twenty-seventh embodiment includes the components of the twenty-third embodiment and includes means for determining whether the power management signal frequency is within a second frequency difference of the second resonant frequency, And to cause the output voltage of the power circuit portion to change to a third output voltage that is separate from the first output voltage and the second output voltage, in response to being in the second frequency difference do.

The 28th embodiment includes frequency generation logic for generating a signal having a selectable signal frequency in a band of frequencies, a first pin for outputting a signal to a power supply, a second pin for receiving a first power at a first voltage from the power supply And a current measurement logic for measuring the current provided to the first pin by the frequency generation logic. The frequency generation logic is for varying the signal frequency within the band of frequencies, and in response to a first increase in the current detected by the current measurement logic when the signal frequency approaches the first frequency of the band of frequencies, The logic is for locking the signal frequency at a first lock frequency which is approximately the first frequency and when locking the signal frequency at the first lock frequency the second pin is connected to the second To receive power.

The twenty-ninth embodiment further includes a universal serial bus (USB) port comprising the components of the twenty-eighth embodiment and including a first pin and a second pin, the USB port for coupling to a USB connector of the power supply .

The thirtieth embodiment includes the constituent elements of the twenty-eighth embodiment. Additionally, in response to a second increase in the current detected by the current measurement logic when the signal frequency approaches the second frequency of the band of frequencies, the frequency generation logic generates the signal frequency at the second lock frequency, which is approximately the second frequency Locking the signal frequency at the second lock frequency and the second pin is for receiving the third power at the third voltage from the power supply.

The thirty-first embodiment includes the steps of generating a signal having a selectable signal frequency in a band of frequencies by signal generation logic of the device, outputting the signal to a power supply, Measuring the current provided to the power supply by the frequency generation logic by means of the current measurement logic of the device; varying the signal frequency in a band of frequencies; Locking the signal frequency at a first lock frequency that is approximately a first frequency in response to detecting a first increase in current when proximate to a first frequency. When locking the signal frequency at the first lock frequency, the second power at the second voltage is intended to be received from the power supply.

The thirty-second embodiment includes the components of the thirty first embodiment, and in response to the detection of a second increase in the current when the signal frequency approaches the second frequency of the band of frequencies, Locking the signal frequency at a frequency where the third power at the third voltage is to be received from the power supply when locking the signal frequency at the second lock frequency.

Embodiments may be used in many different types of systems. For example, in one embodiment, the communication device may be arranged to perform the various methods and techniques described herein. Of course, the scope of the present invention is not limited to communication devices, and instead, other embodiments may be practiced with other types of devices for processing instructions, or in response to being executed on a computing device, And one or more machine readable media including instructions for causing one or more of the techniques to be performed.

Embodiments may be embodied in code or may be stored on non-volatile storage medium that stores instructions that may be used to program the system to perform the instructions. Embodiments may also be implemented as data and may be stored on a non-transitory storage medium that, when used by at least one machine, causes the at least one machine to produce at least one integrated circuit to perform one or more operations have. The storage medium may be selected from the group consisting of floppy disks, optical disks, solid state drives (SSDs), compact disk read-only memory (CD-ROMs), compact disk rewritable read-only memory (ROM), random access memory (RAM), random-access memory (RAM), read-only memory For example, dynamic random access memory (DRAM), static random access memory (SRAM), erasable programmable read-only memory (EPROMs), flash memories, electrically erasable programmable read-only memory (EEPROMs), magnetic or optical cards, or electronic instructions But it may include any suitable other type of media to field, but is not limited to this.

While the invention has been described with respect to a limited number of embodiments, those skilled in the art will recognize many modifications and variations therefrom. The appended claims are intended to cover all such modifications and variations as fall within the true spirit and scope of the present invention.

Claims (25)

As an apparatus,
Detector logic having a first resonant frequency, the detector logic receiving a power management signal having a power management signal frequency, the detector logic determining whether the power management signal frequency is within a first frequency difference of the first resonant frequency - and
Responsive to an indication that the power management signal frequency is within the first frequency difference of the first resonant frequency, causing the power adapter circuitry to change the output voltage from a first voltage to a second voltage that is separate from the first voltage, The switch signal logic for activating the first switching signal to cause the first switching signal to be activated. 2. The power supply according to claim 1, further comprising a power adapter circuit for inputting an alternating current (AC) and outputting a direct current (DC) at an output voltage selected from a plurality of selectable output voltages, In response to receiving the first switching signal, the power adapter circuit portion changes the output voltage from the first voltage to the second voltage. 3. The apparatus of claim 2, wherein the power adapter circuitry provides the output voltage to a universal serial bus (USB) connector. The apparatus of claim 3, further comprising the USB connector. The method of claim 1, further comprising: responsive to a change in the power management signal frequency from a first frequency within a first difference frequency of the resonance frequency to a second frequency outside the first frequency difference of the resonance frequency Wherein the switch signal logic deactivates the first switching signal and upon deactivation of the first switching signal, the output voltage changes from the second voltage to the first voltage. 2. The apparatus of claim 1, wherein the second voltage is greater than the first voltage. 7. The apparatus of claim 6, wherein the first voltage is approximately 5 volts and the second voltage is approximately 12 volts. 2. The method of claim 1 wherein the detector logic has a second resonant frequency and the detector logic provides an indication of whether the power management signal frequency is within a second frequency difference of the second resonant frequency, In response to the indication that the second frequency difference of the second resonant frequency is within the second frequency difference, the switch signal logic causes the power adapter circuitry to output a third voltage that is separate from the first voltage and distinct from the second voltage The second switching signal to activate the second switching signal. 2. The method of claim 1, wherein upon recognition of an indication that the power management signal frequency is within the first frequency difference of the first resonant frequency, the switch signal logic is configured to enable the detector logic to detect the power management signal To cause the power adapter circuitry to change the output voltage from the first voltage to the second voltage after expiration of a blank time interval that begins when the blanking interval begins. 10. The apparatus of any one of claims 1 to 9, wherein the detector logic comprises a resonant circuit portion having a resonant frequency that is the first resonant frequency. 11. The apparatus of claim 10, wherein the resonant circuit portion comprises an inductor-capacitor (L-C) tank circuit. As a method,
In the detector logic, receiving a power management signal having a power management signal frequency;
Determining whether the power management signal frequency is within a first frequency difference of a first resonance frequency; And
Responsive to the power management signal frequency being within the first frequency difference of the first resonant frequency, the output voltage of the power circuit portion is switched from a first output voltage to a second output voltage that is separate from the first output voltage And providing a first indication to enable the first indication. 13. The method of claim 12, wherein after the output voltage of the power logic is switched to the second output voltage, the power management signal frequency is shifted to a second power management signal frequency , Providing a second indication for causing the output voltage of the power circuit portion to be switched to the first output voltage. 13. The method of claim 12, wherein when the power management signal frequency is within the first frequency difference of the first resonant frequency, the output voltage of the power circuit portion is reduced from the first output voltage 2 output voltage. 13. The method of claim 12, wherein the second output voltage is higher than the first output voltage. 13. The method of claim 12, further comprising: determining whether the power management signal frequency is within a second frequency difference of a second resonant frequency; And
Responsive to the power management signal frequency being within the second frequency difference of the second resonant frequency, causing the output voltage of the power circuit portion to reach a third output voltage that is separate from the first output voltage and the second output voltage Further comprising: providing a second indication to cause the second indication to be changed. An apparatus for performing the method of any one of claims 12 to 16. 17. A computer-readable medium storing processor executable instructions,
The instructions, when executed by a processor, cause the processor to:
In the power management logic, to receive a power management signal having a power management signal frequency;
Determine whether the power management signal frequency is within a first frequency difference of a first resonance frequency;
In response to the power management signal frequency being within the first frequency difference of the first resonant frequency, switching the output voltage of the power circuit portion from a first output voltage to a second output voltage that is separate from the first output voltage Gt; computer-readable medium. ≪ / RTI > 19. The method of claim 18, wherein after the output voltage of the power logic is switched to the second output voltage, the power management signal frequency is greater than a second power management signal frequency Further comprising instructions for switching the output voltage of the power circuit portion to the first output voltage in response to having the first output voltage. 19. The method of claim 18, wherein the blank time interval expires before switching the output voltage of the power circuit portion to the second output voltage when the power management signal frequency is within the first frequency difference of the first resonance frequency Wherein the blank time interval begins at an initial time of the determination that the power management signal frequency is within the first frequency difference of the first resonant frequency. 21. The method according to any one of claims 18 to 20,
Determine whether the power management signal frequency is within a second frequency difference of a second resonant frequency;
Responsive to the power management signal frequency being within the second frequency difference of the second resonant frequency, converting the output voltage of the power circuit portion into a third output voltage that is separate from the first output voltage and the second output voltage To change
≪ / RTI > further comprising instructions. As an apparatus,
Means for receiving a power management signal having a power management signal frequency;
Means for determining whether the power management signal frequency is within a first frequency difference of a first resonance frequency; And
Responsive to the power management signal frequency being within the first frequency difference of the first resonant frequency, the output voltage of the power circuit portion is switched from a first output voltage to a second output voltage that is separate from the first output voltage And means for providing a first indication to enable the first indication. 23. The method of claim 22, wherein, after the output voltage of the power logic is switched to the second output voltage, the power management signal frequency is greater than a second power management signal frequency Further comprising means for providing a second indication for causing the output voltage of the power circuit portion to be switched to the first output voltage in response to the change to the first output voltage. As an apparatus,
Frequency generation logic for generating a signal having a selectable signal frequency in a band of frequencies;
A first pin for outputting the signal to a power source;
A second pin for receiving a first power at a first voltage from the power supply; And
And current measurement logic for measuring the current provided to the first pin by the frequency generation logic,
Wherein the frequency generation logic varies the signal frequency within a band of frequencies and in response to a first increase in the current detected by the current measurement logic when the signal frequency approaches a first frequency of a band of frequencies Wherein the frequency generation logic locks the signal frequency at a first lock frequency that is approximately a first frequency and when locking the signal frequency at the first lock frequency, Lt; RTI ID = 0.0 > 2 < / RTI > 25. The apparatus of claim 24, further comprising: a universal serial bus (USB) port comprising the first pin and the second pin, the USB port for coupling to a USB connector of the power source.

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