Patent Application
20160329730
The disclosure generally relates to a mobile device and, more particularly, to a mobile device charging system and related adaptive power converter and charging control circuit.
The battery capacity is the major bottleneck to the usage time of a mobile device, and the time required for charging the battery is proportional to the battery capacity. The charging speed of the mobile device can be improved by increasing the current transmitted through the charging cable, but large current flowing through the charging cable easily results in overheat problem to the charging cable or associated connector and may thus cause danger during the charging process.
To avoid causing danger during the charging process, the circuitry components of the conventional charging device and the charging cable are designed to have matched specifications. Accordingly, the charging device can only cooperate with a dedicated charging cable, and the user is not permitted to replace the charging cable with another charging cable having different specification. Since the architecture of the conventional charging device severely restricts the replacement flexibility of the charging cable, the usage convenience and application scope of the conventional charging device is greatly reduced.
An example embodiment of a mobile device charging system is disclosed, comprising: a mobile charger and a mobile device. The mobile charger comprises: a power converting circuit, arranged to operably convert a source voltage signal and a source current signal into a DC voltage signal and a DC current signal; a communication interface, arranged to operably transmit a data signal and to operably output the DC voltage signal and the DC current signal, wherein a power output path is arranged between the power converting circuit and the communication interface; an output switch, positioned on the power output path; a charger-side sensing circuit, arranged to operably sense the signal on the power output path; a charger-side control circuit, coupled with the power converting circuit and the communication interface, arranged to operably receive the data signal and to operably control operations of the power converting circuit and the output switch; an output terminal; and a charging cable, coupled between the communication interface and the output terminal, arranged to operably transmit the data signal and capable of receiving the DC voltage signal and the DC current signal to provide an output voltage signal and an output current signal at the output terminal. The mobile device comprises: a device-side connector, for detachably connecting with the output terminal to receive power transmitted from the output terminal; a battery, wherein a power input path is arranged between the device-side connector and the battery; an input switch, positioned on the power input path; a device-side sensing circuit, arranged to operably sense signal on the power input path; and a device-side control circuit, coupled with the device-side connector, the input switch, and the device-side sensing circuit, arranged to operably control the input switch and capable of generating and transmitting the data signal to the charger-side control circuit through the device-side connector, the charging cable, and the communication interface; wherein the charger-side control circuit is capable of controlling the power converting circuit to adjust magnitude of at least one of the DC current signal and the DC voltage signal based on content of the data signal so as to control a voltage drop of the charging cable to be less than a predetermined threshold.
Another example embodiment of an adaptive power converter of a mobile charger is disclosed. The mobile charger is utilized for charging a mobile device and comprises an output terminal and a charging cable. The charging cable is coupled with the output terminal and arranged to operably transmit a data signal and capable of receiving a DC voltage signal and a DC current signal to provide an output voltage signal and an output current signal at the output terminal. The mobile device comprises a device-side connector and a battery. The device-side connector is utilized for detachably connecting with the output terminal to receive power transmitted from the output terminal. A power input path is arranged between the device-side connector and the battery. The adaptive power converter comprises: a power converting circuit, arranged to operably convert a source voltage signal and a source current signal into the DC voltage signal and the DC current signal; a communication interface, arranged to operably transmit the data signal and to operably output the DC voltage signal and the DC current signal to the charging cable, wherein a power output path is arranged between the power converting circuit and the communication interface; and a charger-side control circuit, coupled with the power converting circuit and the communication interface, arranged to operably receive the data signal and to operably control operations of the power converting circuit; wherein the mobile device is capable of transmitting the data signal to the charger-side control circuit through the device-side connector, the charging cable, and the communication interface based on sensing result in respect of the signal on the power input path, and the charger-side control circuit is capable of controlling the power converting circuit to adjust magnitude of at least one of the DC current signal and the DC voltage signal based on content of the data signal so as to control a voltage drop of the charging cable to be less than a predetermined threshold.
Another example embodiment of a charging control circuit of a mobile device is disclosed. The mobile device can be charged by a mobile charger. The mobile charger comprises an adaptive power converter, an output terminal, and a charging cable. The adaptive power converter comprises a power converting circuit and a communication interface. The power converting circuit is utilized for converting a source voltage signal and a source current signal into a DC voltage signal and a DC current signal. The communication interface is utilized for transmitting a data signal and outputting the DC voltage signal and the DC current signal. A power output path is arranged between the power converting circuit and the communication interface. The charging cable is coupled between the adaptive power converter and the output terminal and utilized for transmitting the data signal and capable of receiving the DC voltage signal and the DC current signal to provide an output voltage signal and an output current signal at the output terminal. The mobile device comprises a device-side connector and a battery. The device-side connector is utilized for detachably connecting with the output terminal to receive power transmitted from the output terminal. A power input path is arranged between the device-side connector and the battery. The charging control circuit comprises: an input switch, positioned on the power input path; and a device-side control circuit, coupled with the device-side connector and the input switch, arranged to operably control the input switch and capable of transmitting the data signal to the adaptive power converter through the device-side connector, the charging cable, and the communication interface based on sensing result in respect of signal on the power input path, and the adaptive power converter is capable of controlling the power converting circuit to adjust magnitude of at least one of the DC current signal and the DC voltage signal based on content of the data signal so as to control a voltage drop of the charging cable to be less than a predetermined threshold.
Both the foregoing general description and the following detailed description are examples and explanatory only, and are not restrictive of the invention as claimed.
Reference is made in detail to embodiments of the invention, which are illustrated in the accompanying drawings. The same reference numbers may be used throughout the drawings to refer to the same or like parts, components, or operations.
The mobile charger 102 comprises an adaptive power converter 110, an output terminal 120, and a charging cable 130. The adaptive power converter 110 is arranged to operably receive data signals and capable of generating a DC voltage signal and a DC current signal. The charging cable 130 is coupled between the adaptive power converter 110 and the output terminal 120, and arranged to operably transmit the data signals and capable of receiving the DC voltage signal and DC current signal generated by the adaptive power converter 110 to provide an output voltage signal and an output current signal at the output terminal 120.
The mobile device 104 comprises a device-side connector 140, a battery 150, and a charging control circuit 160. The device-side connector 140 is utilized for detachably connecting with the output terminal 120 to receive the power transmitted from the output terminal 120, and there is a power input path arranged between the device-side connector 140 and the battery 150. The charging control circuit 160 is coupled with the device-side connector 140 and capable of generating and transmitting the data signals to the adaptive power converter 110 through the device-side connector 140 and the charging cable 130.
The adaptive power converter 110 of the mobile charger 102 is arranged to operably adjust the magnitude of the DC voltage signal or the DC current signals based on the content of the data signal transmitted from the charging control circuit 160, so as to control the voltage drop of the charging cable 130 to be less than a predetermined threshold.
In the adaptive power converter 110, the power converting circuit 211 is arranged to operably convert a source voltage signal Vs and a source current signal Is into a DC voltage signal Vdc and a DC current signal Idc. The communication interface 213 is arranged to operably transmit a data signal DATA, and there is a power output path arranged between the power converting circuit 211 and the communication interface 213. The communication interface 213 is capable of outputting the DC voltage signal Vdc and the DC current signal Idc to the charging cable 130, so that the charging cable 130 provides the output voltage signal Vout and the output current signal Iout to the output terminal 120. The output switch 215 is positioned on the aforementioned power output path, and utilized for selectively conducting the DC voltage signal Vdc and the DC current signal Idc generated by the power converting circuit 211 to the communication interface 213. The charger-side sensing circuit 217 is arranged to operably sense the signals on the power output path (e.g., the signal Vdc or the signal Idc) to generate a corresponding output voltage sensing signal Svo and/or an output current sensing signal Sio. The charger-side control circuit 219 is coupled with the power converting circuit 211 and the communication interface 213, and arranged to operably receive the data signal DATA.
In practice, the charger-side sensing circuit 217 may be coupled with the signal path between the power converting circuit 211 and the output switch 215 to sense the signal on the signal path between the power converting circuit 211 and the output switch 215. The charger-side sensing circuit 217 may be coupled with the signal path between the output switch 215 and the communication interface 213 to sense the signal on the signal path between the output switch 215 and the communication interface 213.
In operations, the charger-side control circuit 219 controls the operations of the power converting circuit 211 and the output switch 215 based on the content of the received data signal DATA and/or the sensing result of the charger-side sensing circuit 217 in respect of the signals on the power output path, so as to control the voltage drop of the charging cable 130 to be less than the predetermined threshold.
Depending upon the source device or the type of the source voltage signal Vs and the source current signal Is, the power converting circuit 211 may be implemented with various appropriate boost power converter, buck power converter, buck-boost power converter, or flyback power converter. In other words, the source voltage signal Vs may be an AC voltage signal or a DC voltage signal, and the magnitude of the DC voltage signal Vdc may be greater than that of the source voltage signal Vs or may be lower than that of the source voltage signal Vs. Similarly, the magnitude of the DC current signal Idc may be greater than that of the source current signal Is or may be lower than that of the source current signal Is.
As long as the mobile device 104 can sustain, the DC current signal Idc generated by the power converting circuit 211 may be configured to be 5A, 8A, 10A, or an even larger current value to effectively increase the charging speed of the mobile device 104.
In practice, different functional blocks of the adaptive power converter 110 may be realized with separate circuits, or may be integrated into a single circuit chip. In addition, the output switch 215, the charger-side sensing circuit 217, and/or some components of the power converting circuit 211 (e.g., the power switch and inductive elements, not shown in
In the charging cable 130, the power transmission line 221 is utilized for transmitting the power supplied from the adaptive power converter 110 to the mobile device 104, and the data transmission line 223 is utilized for transmitting the data signal DATA. The parasitic resistance 225 of the power transmission line 221 may cause a certain voltage drop of the charging cable 130, but the magnitudes of the output voltage signal Vout and the output current signal Iout provided from the charging cable 130 to the output terminal 120 are typically proportional to the magnitudes of the DC voltage signal Vdc and the DC current signal Idc.
In practice, the charging cable 130 may be realized with various transmission cables capable of simultaneously transmitting power and data. For example, the charging cable 130 may be realized with the USB cable in some embodiments. In this situation, the data signal DATA may be realized with the D+ and D− signals defined by USB series specifications, or may be realized with the CC1 and CC2 signals defined by USB-PD (Universal Serial Bus Power Delivery) series specifications.
In the charging control circuit 160, the input switch 261 is positioned on the power input path between the device-side connector 140 and the battery 150. The input switch 261 is utilized for selectively conducting an input voltage signal Vin and an input current signal Iin which are actually received by the device-side connector 140 to the input terminal of the battery 150 to form a charging voltage signal VB and a charging current signal IB of the battery 150. The device-side sensing circuit 263 is arranged to operably sense the signal on the power input path (e.g., the signal Vin, Iin, VB, and/or IB) to generate a corresponding input voltage sensing signal Svi and/or an input current sensing signal Sii. The device-side control circuit 265 is coupled with the device-side connector 140, the input switch 261, and the device-side sensing circuit 263. The device-side control circuit 265 is arranged to operably control the input switch 261 based on the sensing result of the device-side sensing circuit 263 in respect of the signal on the power input path, to prevent the magnitude of the charging voltage signal VB and/or the charging current signal IB of the battery 150 to exceed a safety level. In addition, the device-side control circuit 265 is also capable of generating and transmitting the data signal DATA to the charger-side control circuit 219 through the device-side connector 140, the charging cable 130, and the communication interface 213 based on the sensing result of the device-side sensing circuit 263 in respect of the signal on the power input path.
In practice, the device-side sensing circuit 263 may be coupled with the signal path between the device-side connector 140 and the input switch 261 to sense the signal (e.g., signal Vin and/or signal Iin) on the signal path between the device-side connector 140 and the input switch 261. The device-side sensing circuit 263 may be coupled with the signal path between the input switch 261 and the battery 150 to sense the signal (e.g., signal VB and/or signal IB) on the signal path between the input switch 261 and the battery 150.
Additionally, different functional blocks of the charging control circuit 160 may be realized with separate circuits, or may be integrated into a single circuit chip. For example, the device-side sensing circuit 263 may be instead arranged outside the charging control circuit 160 (e.g., arranged on a circuit board connecting with the charging control circuit 160) while the other functional blocks of the charging control circuit 160 are integrated into a single chip.
For simplicity of illustration, other components in the adaptive power converter 110, the charging cable 130, and the charging control circuit 160, and their connection relationships are not illustrated in
In practice, the mobile charger 102 may be implemented as a power adapter, a mobile power bank, a car charger, or any other device capable of supplying programmable DC voltage and current in response to the instruction of the mobile device 104.
Additionally, the mobile device 104 may be realized with various portable electronic devices, such as a mobile phone, a tablet PC, a notebook computer, a netbook computer, a portable video display, or the like.
The charging cable 130 typically has a certain parasitic resistance, and the value of the parasitic resistance is correlated with the length of the charging cable 130. Accordingly, the voltage and/or current actually received by the mobile device 104 is lower than the DC voltage and DC current generated by the adaptive power converter 110. In addition, different the charging cable 130 causes different voltage drop, and the same charging cable 130 may has different voltage drop in different life stages or in different operating environments.
In order to offer the user replacement flexibility of the charging cable 130 while maintaining the safety during the charging process, the adaptive power converter 110 or the charging control circuit 160 is arranged to dynamically estimate the voltage drop of the charging cable 130 based on the sensing result in respect of the signal on the power input path (e.g., signal Vin, Iin, VB, and/or IB). Then the adaptive power converter 110 or the charging control circuit 160 may further instruct the power converting circuit 211 to adjust the magnitude of the DC voltage signal Vdc and the DC current signal Idc based on the voltage drop estimation, so as to control the voltage drop of the charging cable 130 to be less than a predetermined threshold.
Please refer to
In the embodiment of
The first DAC 310 is coupled with the power converting circuit 211, and arranged to operably generate a reference current signal Iref according to a first digital value D1 and to operably utilize the reference current signal Iref to control the power converting circuit 211 to adjust the magnitude of the DC current signal Idc. The second DAC 320 is coupled with the power converting circuit 211, and arranged to operably generate a reference voltage signal Vref according to a second digital value D2 and to operably utilize the reference voltage signal Vref to control the power converting circuit 211 to adjust the magnitude of the DC voltage signal Vdc. The first charger-side ADC 330 is coupled between the charger-side sensing circuit 217 and the charger-side digital processing circuit 350, and arranged to convert the output voltage sensing signal Svo into an output voltage sensing value Dvo. The second charger-side ADC 340 is coupled between the charger-side sensing circuit 217 and the charger-side digital processing circuit 350, and arranged to operably convert the output current sensing signal Sio into an output current sensing value Dio. The charger-side digital processing circuit 350 is coupled with the communication interface 213, the first DAC 310, and the second DAC 320. The charger-side digital processing circuit 350 is capable of calculating a charger-side current value CSV based on the output voltage sensing value Dvo and calculating a charger-side current value CSI based on the output current sensing value Dio.
The charger-side control circuit 219 of the embodiment of
In the embodiment of
For example, when the charger-side multiplexer 440 outputs the output voltage sensing signal Svo to the first charger-side ADC 330, the charger-side digital processing circuit 350 may calculate the charger-side current value CSV based on the charger-side sensing value Dout generated by the first charger-side ADC 330. When the charger-side multiplexer 440 outputs the output current sensing signal Sio to the first charger-side ADC 330, the charger-side digital processing circuit 350 may calculate the charger-side current value CSI based on the charger-side sensing value Dout generated by the first charger-side ADC 330.
In the adaptive power converter 110, the power converting circuit 211 may adopt various existing current loop control mechanism to control the magnitude of the DC current signal Idc based on the reference current signal Iref. Similarly, the power converting circuit 211 may adopt various existing voltage loop control mechanism to control the magnitude of the DC voltage signal Vdc based on the reference voltage signal Vref. In practice, the power converting circuit 211 may perform only one of the aforementioned current loop control mechanism and voltage loop control mechanism at a time instead of simultaneously performing moth mechanisms, so as to simplify the circuitry control complexity.
The charger-side digital processing circuit 350 is capable of adjusting the first digital value D1 or the second digital value D2 based on the content of the data signal DATA, the charger-side current value CSV, and/or the charger-side current value CSI transmitted from the communication interface 213, and capable of generating a charger-side switch signal SW1 to control the switching operation of the output switch 215.
The charger-side digital processing circuit 350 may adjust the first digital value D1 or the second digital value D2 based on the content of the data signal DATA, the charger-side current value CSV, and/or the charger-side current value CSI to thereby adjust the magnitude of the reference voltage signal Vref or the reference current signal Iref, so as to conduct a close loop control within the charger-side control circuit 219. As a result, the accuracy of the DC current signal Idc and the DC voltage signal Vdc generated by the power converting circuit 211 can be further increased.
In some embodiments, the charger-side digital processing circuit 350 may transmit the charger-side current value CSV or the charger-side current value CSI to the device-side control circuit 265 of the mobile device 104 through the data signal DATA.
In practice, a charger-side driver circuit 360 may be arranged between the charger-side digital processing circuit 350 and the output switch 215 to drive the charger-side switch signal SW1.
Please refer to
In the embodiment of
The device-side control circuit 265 of the embodiment of
In the embodiment of
For example, when the device-side multiplexer 620 outputs the input voltage sensing signal Svi to the first device-side ADC 510, device-side digital processing circuit 530 may calculate the device-side voltage value DSV based on the device-side sensing value Din generated by the first device-side ADC 510. When the device-side multiplexer 620 outputs the input current sensing signal Sii to the first device-side ADC 510, device-side digital processing circuit 530 may calculate the device-side current value DSI based on the device-side sensing value Din generated by the first device-side ADC 510.
In the charging control circuit 160, the device-side digital processing circuit 530 is capable of generating the device-side switch signal SW2 for controlling the input switch 261 based on the device-side voltage value DSV or the device-side current value DSI to thereby control the magnitude of the charging voltage signal VB and the charging current signal IB of the battery 150.
For example, when the device-side digital processing circuit 530 determines that the charging voltage signal VB or the charging current signal IB exceeds (or below) an acceptable range based on the device-side voltage value DSV or the device-side current value DSI, the device-side digital processing circuit 530 may utilize the device-side switch signal SW2 to turn off the input switch 261. When the battery 150 is fully charged or charged to a predetermined level, the device-side digital processing circuit 530 may utilize the device-side switch signal SW2 to turn off the input switch 261 to avoid the battery 150 to be over charged.
In some embodiments, the device-side digital processing circuit 530 may use the device-side voltage value DSV or the device-side current value DSI to conduct related judgement to generate the data signal DATA, or may transmit the device-side voltage value DSV or the device-side current value DSI to the charger-side control circuit 219 of the adaptive power converter 110 through the data signal DATA.
In operations, the device-side control circuit 265 may turn off the input switch 261 when the device-side voltage value DSV exceeds a threshold voltage value or when the device-side current value DSI exceeds a threshold current value to protect the battery 150 and related circuits.
In practice, a device-side driver circuit 540 may be arranged between the device-side digital processing circuit 530 and the input switch 261 to drive the device-side switch signal SW2.
The actual operating environment of the mobile device charging system 100 is mainly determined by the user's demand and habit. Therefore, some foreign objects may enter the opening of the device-side connector 140 of the mobile device 104 due to the operating environment issues. For example, when the user put the mobile device charging system 100 in the pocket, backpack, or handbag, the floss, hair, textile fiber, or other tiny object may enter the opening of the device-side connector 140 and contact with the conducting pins of the device-side connector 140.
Once the foreign object is conductive, an abnormal current path may occur at the opening of the device-side connector 140 and cause leakage current.
For example,
In order to increase the safety during the charging process, the adaptive power converter 110 or the charging control circuit 160 is capable of dynamically determining whether any abnormal leakage current exists in the power transmission path between the mobile charger 102 and the mobile device 104 (e.g., at the device-side connector 140) based on the sensing result in respect of the signal on the power input path (e.g., the signal Vin, Iin, VB, and/or IB).
The operations of the mobile device charging system 100 will be further described in more details by reference to
When the output terminal 120 of the mobile charger 102 is coupled with the device-side connector 140 of the mobile device 104, the charging control circuit 160 and the adaptive power converter 110 may communicate through the charging cable 130 to conduct one-way or two-way communications.
When the charging control circuit 160 requires the adaptive power converter 110 to supply power for charging the mobile device 104, the device-side control circuit 265 may perform the operation 810 in
In the operation 810, the device-side control circuit 265 may transmit related instructions to the charger-side control circuit 219 of the adaptive power converter 110 through the data signal DATA. For example, the device-side digital processing circuit 530 of the device-side control circuit 265 may transmit a target voltage value VTG and/or a target current value ITG to the charger-side digital processing circuit 350 of the charger-side control circuit 219 through the data signal DATA in the operation 810.
Then, the charger-side control circuit 219 performs the operation 820.
In the operation 820, the charger-side control circuit 219 may control the power converting circuit 211 to generate corresponding DC voltage signal Vdc and DC current signal Idc. For example, the charger-side digital processing circuit 350 of the charger-side control circuit 219 may adjust the aforementioned first digital value D1 and second digital value D2 based on the content of the data signal DATA, so as to utilize the reference current signal Iref to control the power converting circuit 211 to adjust the magnitude of the DC current signal Idc, and to utilize the reference voltage signal Vref to control the power converting circuit 211 to adjust the magnitude of the DC voltage signal Vdc.
In the operation 830, the charging cable 130 receives the DC voltage signal Vdc and the DC current signal Idc generated by the power converting circuit 211 through the communication interface 213 to provide the output voltage signal Vout and the output current signal Iout at the output terminal 120.
In the operation 840, the device-side connector 140 receives the power transmitted from the output terminal 120 to form the input voltage signal Vin and the input current signal Iin actually received by the mobile device 104.
In the operation 850, the device-side sensing circuit 263 may sense the signal on the power input path (e.g., signal Vin, Iin, VB, and/or IB) to generate a corresponding sensing result (such as the aforementioned input voltage sensing signal Svi and/or input current sensing signal Sii). In addition, the device-side control circuit 265 may calculate the corresponding device-side voltage value DSV and/or device-side current value DSI based on the sensing result of the device-side sensing circuit 263.
Alternatively, other computing circuit in the mobile device 104 (not shown) may be employed to calculate the corresponding device-side voltage value DSV and/or device-side current value DSI based on the sensing result of the device-side sensing circuit 263, and then the device-side digital processing circuit 530 reads the device-side voltage value DSV and/or the device-side current value DSI from the computing circuit.
In the operation 860, the charger-side control circuit 219 or the device-side control circuit 265 may dynamically estimate the voltage drop of the charging cable 130 based on the device-side voltage value DSV.
In one embodiment, for example, the device-side digital processing circuit 530 of the device-side control circuit 265 transmits the device-side voltage value DSV corresponding to the signal on the power input path to the charger-side control circuit 219 through the data signal DATA in the operation 860. In this situation, the charger-side control circuit 219 may calculate the corresponding charger-side current value CSV based on the sensing result of the charger-side sensing circuit 217 (e.g., the aforementioned output voltage sensing signal Svo), and calculate a difference between the charger-side current value CSV and the device-side voltage value DSV to generate a voltage drop estimation value of the charging cable 130.
In another embodiment, the charger-side control circuit 219 may calculate the corresponding charger-side current value CSV based on the sensing result of the charger-side sensing circuit 217 in the operation 860, and then transmit the charger-side current value CSV to the device-side digital processing circuit 530 of the device-side control circuit 265 through the data signal DATA. In this situation, the device-side digital processing circuit 530 may calculate a difference between the charger-side current value CSV and the device-side voltage value DSV to generate the voltage drop estimation value of the charging cable 130.
In yet another embodiment, the device-side digital processing circuit 530 of the device-side control circuit 265 may calculate a difference between the target voltage value VTG and the device-side voltage value DSV in the operation 860 to generate the voltage drop estimation value of the charging cable 130.
In the operation 870, the adaptive power converter 110 may control the power converting circuit 211 to adjust the DC current signal Idc or the DC voltage signal Vdc to thereby control the voltage drop of the charging cable 130 to be less than a predetermined threshold.
For example, in some embodiments where the voltage drop estimation value of the charging cable 130 is generated by the charger-side control circuit 219, the charger-side control circuit 219 may control the power converting circuit 211 to adjust the magnitude of at least one of the DC current signal Idc and the DC voltage signal Vdc based on the voltage drop estimation value in the operation 870 to maintain the voltage drop of the charging cable 130 to be less than the predetermined threshold.
In some embodiments where the voltage drop estimation value of the charging cable 130 is generated by the device-side control circuit 265, the device-side digital processing circuit 530 of the device-side control circuit 265 may generate a corresponding adjustment instruction based on the voltage drop estimation value in the operation 870, and then transmit the adjustment instruction to the charger-side control circuit 219 through the data signal DATA. Then, the charger-side control circuit 219 may control the power converting circuit 211 to adjust the magnitude of at least one of the DC current signal Idc and the DC voltage signal Vdc based on the received adjustment instruction to maintain the voltage drop of the charging cable 130 to be less than the predetermined threshold.
In the operation 880, the charger-side control circuit 219 or the device-side control circuit 265 monitor and determine whether abnormal leakage current (e.g., the leakage current Ifb caused by the foreign object 710 at the device-side connector 140) occurs in the power transmission path between the mobile charger 102 and the mobile device 104 based on the device-side current value DSI.
In one embodiment, for example, the device-side digital processing circuit 530 of the device-side control circuit 265 may transmit the device-side current value DSI corresponding to the signal on the power input path to the charger-side control circuit 219 through the data signal DATA in the operation 880. In this situation, the charger-side control circuit 219 may calculate the corresponding charger-side current value CSI based on the sensing result of the charger-side sensing circuit 217 (e.g., the aforementioned output current sensing signal Sio), and utilize the charger-side digital processing circuit 350 to compare the charger-side current value CSI with the device-side current value DSI. If the charger-side current value CSI exceeds the device-side current value DSI by more than a predetermined value, the charger-side digital processing circuit 350 may determine that abnormal leakage current occurs in the power transmission path between the mobile charger 102 and the mobile device 104 (e.g., at the device-side connector 140).
In another embodiment, the charger-side control circuit 219 may calculate the corresponding charger-side current value CSI based on the sensing result of the charger-side sensing circuit 217 in the operation 880, and transmit the charger-side current value CSI to the device-side control circuit 265 through the data signal DATA. In this situation, the device-side digital processing circuit 530 of the device-side control circuit 265 may compare the charger-side current value CSI with the device-side current value DSI. If the charger-side current value CSI exceeds the device-side current value DSI by more than a predetermined value, the device-side digital processing circuit 530 may determine that abnormal leakage current occurs in the power transmission path between the mobile charger 102 and the mobile device 104 (e.g., at the device-side connector 140).
In yet another embodiment, the device-side digital processing circuit 530 of the device-side control circuit 265 may compare the aforementioned target current value ITG with the device-side current value DSI in the operation 880. If the target current value ITG exceeds the device-side current value DSI by more than a predetermined value, the device-side digital processing circuit 530 may determine that abnormal leakage current occurs in the power transmission path between the mobile charger 102 and the mobile device 104 (e.g., at the device-side connector 140).
When the mobile device charging system 100 determines that abnormal leakage current occurs in the power transmission path between the mobile charger 102 and the mobile device 104 in the operation 880, it may proceed to the operation 890; otherwise, it may return to the aforementioned operation 850 to continue monitoring the signal on the power input path.
In the operation 890, the adaptive power converter 110 may turn off the output switch 215 or control the power converting circuit 211 to lower the DC current signal Idc or the DC voltage signal Vdc to reduce the output voltage signal Vout or the output current signal Iout, to thereby reduce or eliminate the leakage current to avoid possible danger that may be caused by the leakage current.
For example, in some embodiments where the charger-side control circuit 219 is employed to determine whether leakage current occurs, the charger-side digital processing circuit 350 in the operation 890 may adjust the charger-side switch signal SW1 to turn off the output switch 215 or control the power converting circuit 211 to lower the magnitude of at least one of the DC current signal Idc and the DC voltage signal Vdc to thereby reduce the magnitude of at least one of the output voltage signal Vout and the output current signal Iout.
In some embodiments where the device-side control circuit 265 is employed to determine whether leakage current occurs, the device-side digital processing circuit 530 in the operation 890 may generate a decrease instruction and transmit the decrease instruction to the charger-side control circuit 219 through the data signal DATA. The charger-side digital processing circuit 350 may adjust the charger-side switch signal SW1 to turn off the output switch 215 or control the power converting circuit 211 to lower the magnitude of at least one of the DC current signal Idc and the DC voltage signal Vdc to thereby reduce the magnitude of at least one of the output voltage signal Vout and the output current signal Iout based on the decrease instruction transmitted from the device-side control circuit 265.
Please refer to
The mobile device charging system 900 is similar with the mobile device charging system 100, but the mobile charger 902 of the mobile device charging system 900 further comprises a receiving terminal 920 and a charger-side connector 940.
As shown in
In other words, the charging cable 130 of the mobile device charging system 900 is indirectly connected with the adaptive power converter 110 through the receiving terminal 920 and the charger-side connector 940, instead of directly connecting with the adaptive power converter 110. Accordingly, the charging cable 130 can be separate from the adaptive power converter 110.
The foregoing descriptions regarding the connections, implementations, operations, and related advantages of other corresponding functional blocks in
Similar with the mobile device charging system 100, the charger-side control circuit 219 or the device-side control circuit 265 of the mobile device charging system 900 is capable of dynamically estimating the voltage drop of the charging cable 130, and then instructing the adaptive power converter 110 to adjust the magnitude of the output DC voltage signal and/or the output DC current signal based on the estimated voltage drop value, so as to control the voltage drop of the charging cable 130 to be less than the predetermined threshold. Accordingly, even the charging cable 130 is replaced by another charging cable with different specifications, the voltage and current supplied from the mobile charger 902 to the mobile device 104 can be maintain in the safe range, without causing overheat problem due to the replacement of the charging cable.
As a result, the user is allowed to replace the charging cable to cooperate with the adaptive power converter 110. For example, the user is allowed to replace the original charging cable 130 with a charging cable having a longer length, capable of carrying larger current, or made by the more reliable materials.
Obviously, the architecture of the aforementioned the mobile device charging system 900 offer more replacement flexibility of the charging cable 130 to the user, thereby greatly improving the usage convenience and application scope of the adaptive power converter 110.
In addition, similar to the mobile device charging system 100, the charger-side control circuit 219 or the device-side control circuit 265 of the mobile device charging system 900 is capable of dynamically determining whether abnormal leakage current occurs in the power transmission path between the mobile charger 102 and the mobile device 104. Accordingly, when the foreign object presents at the device-side connector 140 or the charger-side connector 940 and causes leakage current, the mobile device charging system 900 may perform the aforementioned operation 890 to utilize the adaptive power converter 110 to turn off the output switch 215 or to control the power converting circuit 211 to lower the DC current signal Idc/the DC voltage signal Vdc, so as to reduce the output voltage signal Vout/the output current signal Iout, thereby reducing or eliminating the leakage current.
It can be appreciated from the foregoing descriptions that the mobile chargers 102 and 902 is capable of supplying larger output current signal Iout to the mobile device 104, to thus the charging speed of the mobile device 104 can be effectively increased.
In addition, since the adaptive power converter 110 adaptively adjusts the magnitudes of the DC voltage signal Vdc and the DC current signal Idc based on the instruction of the charging control circuit 160, the mobile chargers 102 and 902 can be employed to charge various types of mobile devices, and thus have a very wide application scope.
Furthermore, since the adaptive power converter 110 or the charging control circuit 160 is capable of dynamically estimating the voltage drop of the charging cable 130 and then conducting adaptive operation to control the voltage drop of the charging cable 130 to be less than the predetermined threshold, different charging cable is thus allowed to be employed to cooperate with the adaptive power converter 110, thereby improving the selection flexibility of the charging cable and also increasing the safety, convenience, and application scope of the mobile chargers 102 and 902.
Additionally, the adaptive power converter 110 or the charging control circuit 160 is also capable of automatically determining whether abnormal leakage current occurs in the power transmission path between the mobile charger 102 and the mobile device 104 or not, and then conducting corresponding operation. Hence, the safety during the charging process can be effectively ensured, thereby lowering the danger when using large current to charge the mobile device.
Please note that the executing order of the operations in
In addition, the output switch 215, the charger-side sensing circuit 217, the charger-side driver circuit 360, and/or the device-side driver circuit 540 may be omitted in some embodiments to simplify the circuitry complexity. Additionally, in the embodiments where the charger-side sensing circuit 217 is omitted, the first charger-side ADC 330, the second charger-side ADC 340, and the charger-side multiplexer 440 in
Certain terms are used throughout the description and the claims to refer to particular components. One skilled in the art appreciates that a component may be referred to as different names. This disclosure does not intend to distinguish between components that differ in name but not in function. In the description and in the claims, the term “comprise” is used in an open-ended fashion, and thus should be interpreted to mean “include, but not limited to.” The tem “couple” is intended to compass any indirect or direct connection. Accordingly, if this disclosure mentioned that a first device is coupled with a second device, it means that the first device may be directly or indirectly connected to the second device through electrical connections, wireless communications, optical communications, or other signal connections with/without other intermediate devices or connection means.
The term “and/or” may comprise any and all combinations of one or more of the associated listed items. In addition, the singular forms “a,” “an,” and “the” herein are intended to comprise the plural forms as well, unless the context clearly indicates otherwise.
The term “voltage signal” used throughout the description and the claims may be expressed in the format of a current in implementations, and the term “current signal” used throughout the description and the claims may be expressed in the format of a voltage in implementations.
Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention indicated by the following claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 201610278760.8 | Apr 2016 | CN | national |
This application claims the benefit of priority to Patent Application No. 201610278760.8, filed in China on Apr. 28, 2016; the entirety of which is incorporated herein by reference for all purposes. This application claims the benefit of priority to U.S. Provisional Application Ser. No. 62/158,460, filed on May 7, 2015; the entirety of which is incorporated herein by reference for all purposes.
| Number | Date | Country | |
|---|---|---|---|
| 62158460 | May 2015 | US |
