CN210691253U - Mobile power supply and communication system - Google Patents

Abstract

The utility model provides a mobile power supply, which comprises a first external interface and a second external interface, wherein the first external interface and the second external interface are both provided with a data terminal and a power terminal, and the data terminal of the first external interface is electrically connected with the data terminal of the second external interface to establish a data transmission channel; the system comprises a first group of interface processing circuits and a second group of interface processing circuits, wherein each group of interface processing circuits comprises a control strategy determination circuit and a voltage regulation circuit; a control circuit; and the power supply circuit is electrically connected with the voltage adjusting circuit, wherein the first group of interface processing circuits are respectively and electrically connected with the first external interface and the control circuit, and the second group of interface processing circuits are respectively and electrically connected with the second external interface and the control circuit.

Description

Mobile power supply and communication system

Technical Field

The present disclosure relates to the field of electronic circuit technology, and in particular, to a mobile power supply and a power supply and communication system.

Background

The AR (Augmented Reality) is a technology for skillfully fusing virtual information and a real world, has been widely applied to various technical means such as multimedia, three-dimensional modeling, real-time tracking and registration, intelligent interaction, sensing and the like, and is applied to the real world after virtual information such as characters, images, three-dimensional models, music, videos and the like generated by a computer is simulated, and the two kinds of information complement each other, so that the real world is enhanced.

At present, a form that AR technique used is intelligent glasses system, and intelligent glasses system includes intelligent glasses and main control end equipment, and intelligent glasses pass through the cable and are connected with the main control end equipment, and the main control end equipment receives the data that intelligent glasses gathered and handles it through the cable, and intelligent glasses then receive the data after the main control end equipment handles through the cable and show. The master control end equipment can also charge the intelligent glasses.

SUMMERY OF THE UTILITY MODEL

In view of the foregoing, the present disclosure provides a mobile power supply and a power supply and communication system. The mobile power supply comprises a first external interface, a second external interface, a first group of interface processing circuits, a second group of interface processing circuits, a control circuit and a power supply circuit. The control strategy determining circuit of each group of interface processing circuits is used for determining a voltage adjusting strategy according to the power supply state information of the corresponding peripheral interface, and the control circuit is used for controlling the voltage adjusting circuit of the interface processing circuits to adjust the voltage output by the power supply circuit according to the voltage adjusting strategy so as to utilize the adjusted voltage to supply power for peripheral equipment coupled with the peripheral interface through the power supply terminal. The mobile power supply can supply power for the peripheral equipment when being electrically connected with the power terminal of the peripheral interface, and the data terminals of the first peripheral interface and the second peripheral interface provide a data communication channel for the peripheral equipment.

According to an aspect of the present disclosure, there is provided a mobile power supply including: the data transmission system comprises a first external interface and a second external interface, wherein the first external interface and the second external interface are both provided with data terminals and power terminals, and the data terminals of the first external interface are electrically connected with the data terminals of the second external interface to establish a data transmission channel; the system comprises a first group of interface processing circuits and a second group of interface processing circuits, wherein each group of interface processing circuits comprises a control strategy determination circuit and a voltage regulation circuit; a control circuit; and a power supply circuit electrically connected to the voltage adjustment circuit, wherein the first group of interface processing circuits are electrically connected to the first peripheral interface and the control circuit, respectively, the second group of interface processing circuits are electrically connected to the second peripheral interface and the control circuit, respectively, the control policy determination circuit is configured to determine a voltage adjustment policy of the voltage adjustment circuit according to power supply status information of the corresponding peripheral interface, and the control circuit is configured to: and controlling the voltage adjusting circuit to perform voltage adjustment on the voltage output by the power supply circuit according to the voltage adjusting strategy so as to utilize the adjusted voltage to supply power to peripheral equipment coupled with the peripheral interface through the power supply terminal.

Optionally, in an example of the above aspect, the data terminal of the first peripheral interface is further configured to output interface state information of the first peripheral interface, and the data terminal of the second peripheral interface is further configured to output interface state information of the second peripheral interface, where the interface state information includes power supply state information;

the first peripheral interface and the second peripheral interface are also provided with interface state information terminals, the interface state information terminals are used for outputting interface state information corresponding to the peripheral interfaces, and the interface state information comprises power supply state information;

each set of interface processing circuits further includes a data communication channel switching circuit, and a data terminal of the first peripheral interface is electrically connected to a data terminal of the second peripheral interface via the data communication channel switching circuit corresponding to the first peripheral interface and the data communication channel switching circuit corresponding to the second peripheral interface, where the control policy determination circuit is configured to: determining a channel switching control strategy of the data communication channel switching circuit according to a corresponding connection mode of the data terminal of the first external interface and the data terminal of the second external interface; and the control circuit is configured to control the data communication channel switching circuit to switch the data communication channel according to the channel switching control strategy, so that the peripheral equipment realizes data communication by establishing a data transmission channel through the respectively connected data terminals;

each group of interface processing circuits further comprises a data communication channel switching circuit, a data terminal of the first peripheral interface is electrically connected with a data terminal of the second peripheral interface through the data communication channel switching circuit corresponding to the first peripheral interface and the data communication channel switching circuit corresponding to the second peripheral interface, wherein the interface state information further comprises equipment insertion direction indication information, the equipment insertion direction indication information is used for indicating the insertion direction of an interface connected with the peripheral interface relative to the peripheral interface, and the control strategy determining circuit is configured to: and the control circuit is configured to control the data communication channel switching circuit to switch the data communication channel according to the channel switching control strategy, so that the peripheral equipment realizes data communication by establishing a data transmission channel through the respectively connected data terminals.

The interface state information further includes data communication indication information, and the control policy determination circuit is configured to determine a channel switching control policy of the data communication channel switching circuit according to the device insertion direction indication information when the data communication indication information indicates that data communication is performed;

the first external interface and the second external interface are both type-c interfaces;

the interface state information further includes power supply mode information, and the control policy determination circuit is configured to determine the voltage adjustment policy from the power supply state information and the power supply mode information;

the mobile power supply supports a PD protocol;

the power supply circuit comprises a power supply conversion circuit used for providing a voltage specified in the mobile power supply;

the power circuit also comprises a battery circuit, and the battery circuit is used for storing energy and supplying power;

the control circuit is integrated as a component with at least one of the following circuits: a control strategy determination circuit; a voltage regulation circuit; and a data communication channel switching circuit;

further comprising a housing, the first set of interface processing circuitry, the second set of interface processing circuitry, the control circuitry, and the power circuitry being disposed inside the housing, and the first peripheral interface and the second peripheral interface being embedded in the housing and exposed;

according to an aspect of the present disclosure, there is provided a power supply and communication system including:

the mobile power supply of any one of the above;

a first peripheral device electrically connected to the mobile power supply via a first peripheral interface;

a second peripheral device electrically connected to the mobile power supply via a second peripheral interface;

the mobile power supply supplies power to the first peripheral equipment through the first peripheral interface and supplies power to the second peripheral equipment through the second peripheral interface; and

the mobile power supply provides a data transmission channel via the first peripheral interface and the second peripheral interface to enable data transmission between the first peripheral device and the second peripheral device.

Optionally, in an example of the above aspect, the first peripheral device includes smart glasses using virtual reality technology, and the second peripheral device includes a master device for controlling the smart glasses.

Drawings

A further understanding of the nature and advantages of the present disclosure may be realized by reference to the following drawings. In the drawings, similar components or features may have the same reference numerals. The accompanying drawings, which are included to provide a further understanding of the embodiments of the disclosure and are incorporated in and constitute a part of this disclosure, illustrate embodiments of the disclosure and together with the detailed description serve to explain the embodiments of the disclosure, but are not intended to limit the embodiments of the disclosure. In the drawings:

FIG. 1 shows a schematic diagram of one scenario in which a cell phone is connected to smart glasses;

fig. 2 shows a block diagram of one example of a mobile power supply of an embodiment of the present disclosure;

FIG. 3(a) is a schematic diagram showing one example of a pin configuration for a type-c socket;

FIG. 3(b) shows a schematic diagram of one example of a pin configuration for a type-c plug;

fig. 4 shows a block diagram of one example of a mobile power supply of another embodiment of the present disclosure;

fig. 5 illustrates a component connection diagram of one example of a mobile power supply of an embodiment of the present disclosure;

fig. 6 shows a circuit diagram of one example of a data communication channel switching circuit of an embodiment of the present disclosure;

fig. 7 shows a component connection diagram of another example of a mobile power supply of an embodiment of the present disclosure;

fig. 8 is a schematic diagram showing one example of data communication channel switching by the data communication channel switching circuit of the embodiment of the present disclosure;

fig. 9 shows a block diagram of a power and communication system of an embodiment of the present disclosure;

FIG. 10 shows a flow diagram of a method for powering a peripheral device of an embodiment of the present disclosure; and

FIG. 11 shows a block diagram of an electronic device for implementing a method of powering a peripheral device of an embodiment of the present disclosure.

Description of the reference numerals

110: the mobile phone 235: data communication channel switching circuit

113: the mobile phone interface 250: control circuit

120: the smart glasses 260: integrated assembly

123: smart glasses interface 270: power supply circuit

130: cable 1100: electronic device

133: the cable interface 1110: processor with a memory having a plurality of memory cells

200: mobile power supply 1120: memory device

210: peripheral interface 1130: memory device

230: the interface processing circuit 1140: communication interface

231: the control policy determination circuit 1150: bus line

233: voltage regulation circuit

Detailed Description

The subject matter described herein will be discussed with reference to example embodiments. It should be understood that these embodiments are discussed only to enable those skilled in the art to better understand and thereby implement the subject matter described herein, and are not intended to limit the scope, applicability, or examples set forth in the claims. Changes may be made in the function and arrangement of elements discussed without departing from the scope of the disclosure. Various examples may omit, substitute, or add various procedures or components as needed. In addition, features described with respect to some examples may also be combined in other examples.

As used herein, the term "include" and its variants mean open-ended terms in the sense of "including, but not limited to. The term "based on" means "based at least in part on". The terms "one embodiment" and "an embodiment" mean "at least one embodiment". The term "another embodiment" means "at least one other embodiment". The terms "first," "second," and the like may refer to different or the same object. Other definitions, whether explicit or implicit, may be included below. The definition of a term is consistent throughout the specification unless the context clearly dictates otherwise.

In this document, the term "connect" refers to a direct mechanical, communication, or electrical connection between two components (or units), or an indirect mechanical, communication, or electrical connection through an intermediate component, between which electrical communication is possible for data/information exchange. The connection may be implemented in a wired manner.

The intelligent glasses system comprises intelligent glasses and main control end equipment, the intelligent glasses are matched with the main control end equipment for use, the intelligent glasses can be connected with the main control end equipment (such as a computer and a mobile phone) in a wired mode (such as a cable), the main control end equipment can provide display data for constructing a virtual environment for the intelligent glasses, and the intelligent glasses can construct the virtual environment based on the data. The following description will be made in detail with reference to fig. 1 by taking smart glasses and a mobile phone as examples.

Fig. 1 shows a schematic diagram of one scenario in which a cell phone 110 is connected to smart glasses 120. As shown in fig. 1, the handset 110 is configured with a handset interface 113, and the handset interface 113 can be used for power receiving, power supplying, data communication, and the like. The smart glasses 120 are configured with a smart glasses interface 123, which smart glasses interface 123 may be used for power reception, data communication, and the like. Cable 130 is provided with cable interfaces 133 at both ends, and the cable interfaces 133 can be used for power transmission, data communication, and the like. The cell phone interface 113, the smart glasses interface 123, and the cable interface 133 are all type-c interfaces.

After the mobile phone 110 is connected to the smart glasses 120 through the cable 130, the mobile phone 110 performs data communication with the smart glasses 120 through the cable 130, for example, the mobile phone 110 may transmit display data, communication signal data, and the like for displaying a virtual object to the smart glasses 120 through the cable 130, and the mobile phone 110 may also supply power to the smart glasses 120 through the cable 130. Power supply and data communication may be performed simultaneously.

However, the energy storage of the battery in the mobile phone 110 is limited, which limits the endurance of the mobile phone 110 as a power supply. In the using process of the smart glasses 120, the smart glasses 120 and the mobile phone 110 consume more power as a system, which results in poor cruising ability of the mobile phone 110 and the smart glasses 120.

In order to solve the above problems, the present disclosure provides a mobile power supply and a power supply and communication system, including a first external interface and a second external interface, where the first external interface and the second external interface both have a data terminal and a power terminal, and the data terminal of the first external interface is electrically connected with the data terminal of the second external interface to establish a data transmission channel; the system comprises a first group of interface processing circuits and a second group of interface processing circuits, wherein each group of interface processing circuits comprises a control strategy determination circuit and a voltage regulation circuit; a control circuit; and the power supply circuit is electrically connected with the voltage adjusting circuit, wherein the first group of interface processing circuits are respectively and electrically connected with the first external interface and the control circuit, and the second group of interface processing circuits are respectively and electrically connected with the second external interface and the control circuit. The mobile power supply can supply power for the peripheral equipment when being electrically connected with the power terminal of the peripheral interface, and the data terminals of the first peripheral interface and the second peripheral interface provide a data communication channel for the peripheral equipment.

A mobile power supply and a power supply and communication system according to the present disclosure will be described in detail below with reference to the accompanying drawings.

Fig. 2 shows a block diagram of one example of a mobile power supply 200 of an embodiment of the present disclosure.

The mobile power supply 200 may include two peripheral interfaces 210, two sets of interface processing circuitry 230, control circuitry 250, and power supply circuitry 270. It should be noted that the mobile power supply 200 may include at least two peripheral interfaces 210 and at least two sets of interface processing circuits 230. As shown in fig. 2, the mobile power supply 200 includes two peripheral interfaces 210: the mobile power supply 200 includes two sets of interface processing circuits 230: a first set of interface processing circuits and a second set of interface processing circuits. Fig. 2 is only an example of the mobile power supply 200, and the following description also applies to the case where the mobile power supply 200 includes more than two peripheral interfaces 210 and more than two interface processing circuits 230. The mobile power supply 200 is described in detail below with reference to fig. 2.

In one example of the present disclosure, the mobile power supply 200 may be portable.

In the present disclosure, the interface processing circuits 230 correspond to the peripheral interfaces 210 one-to-one, and each set of the interface processing circuits 230 is electrically connected to the corresponding peripheral interface 210 and the control circuit 250. The power supply circuit 270 is electrically connected to the voltage adjustment circuit 233.

For peripheral interface 210

In one example, the peripheral interface 210 may be a type-c interface, i.e., the first peripheral interface and the second peripheral interface are both type-c interfaces. Correspondingly, the interface of the peripheral device may also be a type-c interface, and the cable for connecting the peripheral device with the peripheral interface 210 may also be a type-c-type-c cable.

the type-c interface comprises a type-c socket and a type-c plug, the type-c socket and the type-c plug are corresponding, and the type-c plug is inserted into the type-c socket to realize connection.

FIG. 3(a) shows a schematic diagram of one example of a pin configuration for a type-c socket. The schematic view is taken from the outside-in perspective of the socket. As shown in FIG. 3(a), "GND" is a ground pin, and "V_BUS"is the bus power pin. "TX 1 +", "TX 1-", "TX 2 +", "TX 2-", "RX 1 +", "RX 1-", "RX 2 +", and "RX 2-" all represent data transmission pins; "CC 1" and "CC 2" are probing and communication pins for probing the interface insertion direction of the plug and the socket, including the forward insertion direction and the reverse insertion direction, and the uplink and downlink role types of the type-c interface, and implementing the communication of the PD protocol. The SBU1 and SBU2 are multiplexing pins which can be multiplexed into other ports; and the D + and the D-are data transmission pins compatible with the USB2.0 protocol.

Fig. 3(b) shows a schematic diagram of one example of a pin configuration of a type-c plug. The schematic view is taken from the outside-in viewing angle of the plug. As shown in FIG. 3(b), "V_CONNThe "pins" are used to power the chips in the cable. The "CC" pin may determine the interface insertion direction from the connection "CC 1" pin or the "CC 2" pin.

A1, …, a12 and B1, …, B12 in fig. 3(a) and 3(B) above all represent the identification of the pin.

The first peripheral interface and the second peripheral interface may each include a data terminal and a power supply terminal. The power terminal is used for power transmission and the data terminal may be used for data transmission, such as video data, audio data, and the like. In one example, the data terminal may be further configured to transmit interface status information, and in one example, the data terminal of the first peripheral interface may be further configured to output the interface status information of the first peripheral interface, and the data terminal of the second peripheral interface may be further configured to output the interface status information of the second peripheral interface. In this example, the interface state information may be implemented by a software module having a corresponding function. The interface status information may include power supply status information, which may also be implemented by a software module.

In another example, each peripheral interface may further include an interface status information terminal, and in an example, the first peripheral interface and the second peripheral interface further include an interface status information terminal, where the interface status information terminal is configured to output interface status information of the corresponding peripheral interface, and the interface status information may include power supply status information.

The power supply state information is used to indicate whether power needs to be supplied to the peripheral device, and the power supply state information may include information indicating power supply and information indicating no power supply. In one example, the information indicating power supply may include DFP (downlink facing port) information, and when the peripheral interface 210 is determined to be a DFP, the mobile power supply 200 is a host terminal, and the mobile power supply 200 may supply power to the peripheral device as a power supply terminal.

The information indicating that power is not supplied may be based on a request of the peripheral device, and the mobile power supply 200 does not supply power to the outside when the peripheral device requests power to be not supplied. For the mobile power supply 200, in one example, when the peripheral interface 210 is determined to be ufp (upstream Facing port), it indicates that the mobile power supply 200 does not need to supply power to the peripheral device. In another example, where the peripheral interface 210 is determined to be a DFP, the control circuit 250 may control the voltage adjustment circuit to not power the peripheral device.

If the power supply status information corresponding to one peripheral interface 210 may be fixed DFP information, the mobile power source 200 of the peripheral interface 210 serves as a power supply terminal. The power supply state information corresponding to one peripheral interface 210 may be DFP information or UFP information, where the peripheral interface 210 is a drp (dual Role port), and the mobile power supply 200 of the peripheral interface 210 may serve as a power supply end or a power receiving end.

Taking the peripheral interface 210 as the type-c interface as an example, for a device whose power supply status information indicates DFP, CC1 and CC2 of the peripheral interface 210 are set to connect the pull-up resistor R_p. For devices whose power state information indicates UFP, CC1 and CC2 of peripheral interface 210 are set to connect pull-down resistor R_d. For DRP devices, CC1 and CC2 of peripheral interface 210 are arranged to both have pull-up resistor R connected to them_pAnd a pull-down resistor R_dCan pull up the resistor R_pAnd a pull-down resistor R_dWhen switching to the pull-up resistor R_pThe device can be used as a DFP device when switching to pull-down resistor R_dThe device may act as a device for a UFP. Wherein, a pull-up resistor R_pAnd a pull-down resistor R_dMay be specified, e.g. pull-up resistor R_pIs 56K ohm, and a pull-down resistor R_dIs 5.1K ohms.

When the peripheral interface 210 is electrically connected to the peripheral device through a cable, the interface of the cable includes a CC pin, the mobile power supply 200 may detect a resistance of the CC1 or the CC2 in the interface of the peripheral device through the CC pin of the cable, and if it is detected that the resistance of the peripheral device is the pull-down resistance R_dIt may be determined that the peripheral device is in the UFP mode and the mobile power supply 200 is in the DFP mode.

In one example, the pull-up resistor R may be connected across CC1 and CC2 of the peripheral interface 210_p. In another example, CC1 and CC2 of peripheral interface 210 are configured to connect pull-up resistor R_pAnd a pull-down resistor R_dAnd the connection can be switched. For example, when the mobile power supply 200 is connected to a peripheral device, the CC1 and the CC2 may be switched and connected to the pull-up resistor R in a software-controlled manner_p。

It should be noted that the DFP and the UFP are used as power supply and power receiving roles for indicating a power supply direction. In addition, the DFP and UFP may also serve a data master-slave role for indicating a data transfer direction, output data when acting as a data master role DFP, and input data when acting as a data slave role UFP. For example, when a device a is electrically connected to a device B through an interface for data transmission, the device a plays a data master role and the device B plays a data slave role when the interface is determined to be DFP, the device a outputs data to the device B, the device B receives the data output by the device a, and when the interface is determined to be UFP, the device B plays a data master role and the device a plays a data slave role, the device B outputs data to the device a, and the device a receives the data output by the device B.

In the present disclosure, the power terminal of the peripheral interface 210 is used to output or input power, and the mobile power supply 200 supplies power to the peripheral device when the power terminal outputs power, and the peripheral device may supply power to the mobile power supply 200 when the power terminal inputs power.

In the present disclosure, the data terminals of the peripheral interfaces 210 are electrically connected to each other to enable the peripheral interfaces to establish a data transmission channel therebetween for data transmission. The data transmission channel formed by the electrical connection between the data terminal of the first peripheral interface and the data terminal of the second peripheral interface can be used for transmitting data. In one example, the lanes between the data terminals may include a high speed lane, which may be used to transmit data with higher real-time requirements, such as DP data, and a low speed lane. The low speed channel may be used to transmit communication signal data or the like.

The data that can be transmitted between the peripheral interfaces 210 includes USB data, communication signal data, display data, and the like. The USB data is data supported by USB protocols such as USB2.0 and USB3.0, for example, USB2.0 data, and the USB2.0 data is data that can be supported by a data line interface of the USB2.0 protocol for transmission. The USB data and the communication signal data may be transmitted using a low speed channel.

The display data includes DP (displayport) data, which has a high requirement on real-time performance, and the transmission of the DP data can be implemented by a high-speed channel with higher transmission efficiency, so as to ensure the real-time performance of the DP data.

In the present disclosure, the peripheral interface 210 may provide only power or only a data communication channel for the peripheral device, and may also provide both power and a data communication path for the peripheral device.

In one example, peripheral interface 210 may also implement a positive-negative insertion. For example, if the peripheral interface 210 is a socket, the plug can be inserted into the socket positively or negatively, and both insertion modes can be used for connection. Through the implementation of forward and reverse insertion in the example, the user can insert randomly in the using process without confirming the insertion direction in advance, and the user experience is improved.

Processing circuitry 230 for an interface

In one example, the mobile power supply 200 includes a first set of interface processing circuits and a second set of interface processing circuits, each set of interface processing circuits 230 including a control strategy determination circuit 231 and a voltage adjustment circuit 233.

The control strategy determination circuit 231 is configured to determine a voltage adjustment strategy of the voltage adjustment circuit 233 according to the power supply state information. In one example, when the power state information is DFP information, the voltage adjustment policy is to provide power to the peripheral device and the voltage adjustment circuit 233 adjusts the output voltage. When the power supply status information is UFP information, it indicates that power supply to the peripheral device is not required, and the voltage adjustment policy is that the voltage adjustment circuit 233 does not output a voltage.

The voltage adjustment circuit 233 is electrically connected to the power supply circuit 270, and the output of the power supply circuit 270 is electrically connected to the input of the voltage adjustment circuit 233. The voltage adjustment circuit 233 may perform voltage adjustment on the voltage output from the power supply circuit 270.

In one example, the voltage adjustment circuit 233 may employ a buck/boost circuit. In one example, the voltage regulation circuit 233 may be implemented on a chip of the NCP81239 type.

For control circuit 250

The control circuit 250 is communicatively connected to the control strategy determination circuit 231, and the communication connection may be an electrical connection. The control strategy determination circuit 231 may inform the control circuit 250 of the determined voltage adjustment strategy.

The control circuit 250 is configured to: the voltage adjustment circuit 233 is controlled to perform voltage adjustment on the voltage output by the power circuit 270 according to a voltage adjustment strategy to utilize the adjusted voltage to power a peripheral device coupled to the peripheral interface 210 via the power terminal.

For power supply circuit 270

In one example of the present disclosure, the power supply circuit may include a power conversion circuit for providing a voltage specified in the mobile power supply. The voltage specified in the mobile power supply may include, among other things, a rated voltage of a circuit or a component in the mobile power supply. The voltage provided by the power conversion circuit is the voltage obtained by voltage conversion of the input voltage of the power conversion circuit. The input voltage of the power conversion circuit may be derived from an external power source, in which case the input of the power conversion circuit is electrically connected to the output of the external power source. The input voltage of the power conversion circuit may also be derived from the battery voltage in the mobile power supply, in which case the input of the power conversion circuit is electrically connected to the output of the battery.

In one example, the power conversion circuit is a voltage reduction circuit, and the power conversion circuit can convert a supply voltage of an external power supply into a voltage specified in the mobile power supply.

In one example of the present disclosure, the power circuit may further include a battery circuit including a battery, and the battery capacity may be configurable. The battery circuit may be used to store energy and output electrical energy to an external device. The output of the external power source is electrically connected to the input of the battery circuit, and the external power source can charge the battery in the battery circuit to store energy. When the mobile power supply needs to supply power to the external equipment, the battery circuit outputs voltage.

In one example, the output of the battery circuit may also be electrically connected to the control circuit 250, the voltage adjusting circuit 233, the data communication channel switching circuit 235, and other circuits or components in the mobile power supply 200 through a voltage adjusting module, and the power supply module may adjust the voltage output by the battery circuit to the rated voltage of each circuit or component to meet the power supply requirement of each circuit or component.

In one example of the present disclosure, a power supply and communication system includes the above-described mobile power supply 200, a first peripheral device, and a second peripheral device. The mobile power supply 200 is electrically connected to the first peripheral device via the first peripheral interface, and is electrically connected to the second peripheral device via the second peripheral interface. The mobile power supply 200 may supply power to the first peripheral device via the first peripheral interface, and may also supply power to the second peripheral device via the second peripheral interface; the mobile power supply 200 may provide a data transmission channel via the first peripheral interface and the second peripheral interface to enable data transmission between the first peripheral device and the second peripheral device.

In one example, the first peripheral device may include a head mounted display device, the second peripheral device may include a master device for controlling the head mounted display device, the master device may include a mobile phone, a tablet, a computer, and the like, which may control operations, and the head mounted display device may include smart glasses using virtual reality technology, such as AR glasses, VR glasses, XR glasses, and the like. For example, the smart glasses and the mobile phone are electrically connected to the mobile power supply 200 as peripheral devices, and the mobile power supply 200 may supply power to the smart glasses and the mobile phone and provide a data transmission path so that data communication may be performed between the at least two peripheral devices.

Fig. 4 shows a block diagram of one example of a mobile power supply 200 of another embodiment of the present disclosure.

As shown in fig. 4, each set of the interface processing circuits 230 may further include a data communication channel switching circuit 235, where the data terminal of each peripheral interface 210 is electrically connected to establish a data transmission channel through the data communication channel switching circuit 235 of the peripheral interface where the data terminal is located, and in an example, the data terminal of the first peripheral interface is electrically connected to the data terminal of the second peripheral interface to establish a data transmission channel through the data communication channel switching circuit corresponding to the first peripheral interface and the data communication channel switching circuit corresponding to the second peripheral interface.

A plurality of data communication channels may be formed between the data communication channel switching circuits 235, and the data communication channel switching circuits 235 may switch the data communication channels by way of channel switch switching.

In one example of the present specification, the interface state information may further include device insertion direction indication information indicating an insertion direction of an interface connected with the peripheral interface with respect to the peripheral interface. The control strategy determination circuit may be configured to: and determining a channel switching control strategy of the data communication channel switching circuit according to the equipment insertion direction indication information. In one example, the device insertion direction indication information and the channel switching control policy may be in a one-to-one correspondence.

The control circuit is configured to control the data communication channel switching circuit to perform data communication channel switching according to a channel switching control strategy, so that the peripheral equipment establishes data transmission channels through the respective data terminals to realize data communication.

In the present disclosure, the insertion direction of the peripheral device into the peripheral interface includes a forward insertion direction and a reverse insertion direction. The following describes the direction of insertion of the interface with reference to the pin identifiers in fig. 3(a) and 3 (b). A positive insertion direction is indicated when the pin in the plug and the pin in the corresponding socket have the same identification. For example, the a1 pin in the socket is connected to the a1 pin in the plug in the positive insertion direction. When the pin in the plug and the pin in the corresponding socket are not identical in identification, such as when the a1 pin in the socket and the B1 pin in the plug are correspondingly connected, the reverse insertion direction is indicated.

In one example of the present disclosure, the first peripheral interface and the second peripheral interface are both type-c interfaces, and the device insertion direction indication information may be characterized by a peripheral interface terminal name providing power supply state information. The interface status information terminals of the peripheral interface 210 include CC1 and CC2, and CC1 and CC2 are used to characterize an insertion direction, respectively.

When the peripheral device accesses the peripheral interface 210, whether the CC pin is connected to the CC1 pin or the CC2 pin is detected. When the CC pin corresponds to the connection CC1 pin, the device insertion direction indication information is CC1, and the indicated direction is a positive insertion direction. When the CC pin corresponds to the connection CC2 pin, the device insertion direction indication information is CC2, and the indicated direction is the reverse insertion direction.

Fig. 5 shows a component connection diagram of one example of the mobile power supply 200 of an embodiment of the present disclosure. The peripheral interface 210 shown in fig. 5 is a type-c interface, and it should be noted that the peripheral interface 210 is a type-c interface only as an example, and the peripheral interface 210 may also be other types of interfaces having corresponding functions. For example, the components and circuits included in the mobile power supply 200 all conform to the relevant specification and requirements of the type-c interface, at least two peripheral interfaces 210 included in the mobile power supply 200 are interfaces conforming to other specifications, and the components and circuits included in the mobile power supply 200 are electrically connected with the peripheral interfaces 210 after corresponding conversion.

The following description will be made taking a type-c interface as an example.

As shown in fig. 5, the control circuit 250 is electrically connected to the control policy determination circuit 231, the voltage adjustment circuit 233, and the data communication channel switching circuit 235 in each set of interface processing circuits 230. The interface status information terminals of the peripheral interface 210 include CC1 and CC2, the data terminals include D +, D-, TX1, TX2, RX1, RX2 and SBU, and the power terminals include V_BUS。

The two peripheral interfaces 210 are used to transfer USB2.0 data over the path formed by the D + and D-direct connections. By using the path, data of the USB2.0 protocol can be compatible, and the data communication capability of the mobile power supply is improved.

The control strategy determination circuit 231 in each set of interface processing circuits 230 is electrically connected to the CC1 and the CC2 of the peripheral interfaces 210, and in one example, the control circuit 250 is connected to the control strategy determination circuit 231 via an I2C bus.

The data communication channel switching circuit 235 in each set of the interface processing circuits 230 is electrically connected to TX1, TX2, RX1, RX2, and SBU. Wherein, TX1 comprises TX1+ and TX1-, TX2 comprises TX2+ and TX2-, RX1 comprises RX1+ and RX1-, and RX2 comprises RX2+ and RX 2-. SBUs include SBU1 and SBU 2. The channels formed by TX1, TX2, RX1 and RX2 are high-speed channels, and the channels formed by SBUs are low-speed channels, which can be used for transmitting communication signal data.

In one example, when the mobile power supply 200 is electrically connected to a peripheral device via the peripheral interface 210, the control circuit 250 controls the voltage adjustment circuit 233 to supply power to the peripheral device, and based on the insertion direction of the peripheral device, the control circuit 250 controls the data communication channel switching circuit 235 to switch the corresponding data communication channel. After the channel switching is completed, the control circuit 250 notifies the peripheral device that data transmission can be performed through the channel between the data communication channel switching circuits 235.

Fig. 6 shows a circuit diagram of one example of the data communication channel switching circuit 235 of the embodiment of the present disclosure. The data communication channel switching circuit 235 shown in fig. 6 employs a chip of HD3SS460 model. The connection between the data communication channel switching circuit 235 and the corresponding peripheral interface 210 includes: TX1 is connected to CTX1, TX2 is connected to CTX2, RX1 is connected to CRX1, RX2 is connected to CRX2, and SBUs are connected to CSBU1 and CSBU 2.

Each data communication channel switching circuit 235 is electrically connected to the control circuit 250. In one example, the control circuit 250 is electrically connected to the data communication channel switching circuit 235 through an I2C bus, and the data communication channel switching circuit 235 may be controlled through an I2C bus.

In another example, the control circuit 250 is electrically connected to the POL control pin and the AMSEL control pin of the data communication path switching circuit 235. The control circuit 250 inputs high and low levels to the POL control pin and the AMSEL control pin to control the data communication channel switching circuit 235, and different channels can be opened when the levels of the POL control pin and the AMSEL control pin are different.

For example, the data communication channel switching circuit 235 adopts a chip of HD3SS460 type, and when the POL pin inputs a low level and the AMSEL pin inputs a high level, the four-channel mode is turned on; when the POL pin inputs a low level and the AMSEL pin inputs a low level, starting a USBSS channel and a two-channel mode; when the POL pin inputs low level and the AMSEL pin inputs middle level, the USBSS channel mode is started.

Voltage regulation circuits 233 and V in each set of interface processing circuits 230_BUSElectrical connection for adjusting V_BUSThe voltage of (c). In one example, the control circuit 250 is electrically connected to the voltage regulation circuit 233 via an I2C bus to control the voltage regulation circuit 233 via an I2C bus.

In one example of the present disclosure, the control circuit 250 may be integrated with the control policy determination circuit 231 in each set of interface processing circuits into one component that may implement the functions of the control circuit 250 and the control policy determination circuit 231.

In one example of the present disclosure, the control circuit 250 may be integrated as one component with at least one of the control policy determination circuit 231, the voltage adjustment circuit 233, and the data communication channel switching circuit 235.

Taking the control circuit 250 and the control policy determination circuit 231 as an example to be integrated into one component, fig. 7 shows a component connection diagram of another example of the mobile power supply 200 of the embodiment of the present disclosure. As shown in fig. 7, the control circuit 250 and the control policy determination circuit 231 in each set of interface processing circuits are integrated into one component 260, and the component 260 is electrically connected to the peripheral interface 210, the data communication channel switching circuit 235 and the voltage adjustment circuit 233, respectively.

In one example of the present disclosure, the control strategy determination circuit is configured to: and determining a channel switching control strategy of the data communication channel switching circuit according to the equipment insertion direction indication information. The control circuit is configured to control the data communication channel switching circuit to perform data communication channel switching according to a channel switching control policy so that the peripheral devices realize data communication via the respective data terminals.

In this example, the channel switching control policy is used to instruct the data communication channel switching circuit 235 to switch to the corresponding data communication channel. The data communication channel switching circuit 235 includes a channel switch, which switches to different positions corresponding to different data communication paths. The insertion direction indicated by the device insertion direction indication information corresponds to the channel switching control strategy one to one, and the channel switching control strategy corresponds to the position of the channel switch one to one.

For example, the position of the channel switch preset by the data communication channel switching circuit is a position corresponding to a positive insertion direction, when the direction indicated by the device insertion direction indication information is the positive insertion direction, the current position of the channel switch may be kept unchanged, and when the direction indicated by the device insertion direction indication information is the reverse insertion direction, the channel switch may be switched to a position corresponding to the reverse insertion direction.

Fig. 8 is a schematic diagram showing an example of switching of the data communication channel by the data communication channel switching circuit 235 according to the embodiment of the present disclosure. As shown in fig. 8, the data communication channel switching circuit 235 is connected to the peripheral interface 210, and four channel switches in the data communication channel switching circuit 235 are: a channel switch corresponding to TX1, a channel switch corresponding to TX2, a channel switch corresponding to RX1, and a channel switch corresponding to RX 2. The dashed lines in the figure indicate the positions to which the channel switches can be switched. For example, the current position of the channel switch corresponding to TX1 is connection TX1, which can switch to connection TX 2.

The current position (shown in solid lines) of each channel switch shown in fig. 8 corresponds to the positive insertion direction, and the position shown in dotted lines corresponds to the negative insertion direction. When the interface of the peripheral interface 210 and the peripheral device is in the positive insertion direction, TX1, TX2, RX1 and RX2 in the peripheral interface 210 correspond to TX1, TX2, RX1 and RX2 of the connected interface respectively, and the channel switch is placed at the position indicated by the solid line. When the interface of the peripheral interface 210 connected with the peripheral device is in the reverse insertion direction, TX1, TX2, RX1 and RX2 in the peripheral interface 210 correspond to TX2, TX1, RX2 and RX1 of the connected interface respectively, and then the channel switch is placed at the position indicated by the dotted line.

In an example of the present disclosure, each set of the interface processing circuits further includes a data communication channel switching circuit, and the data terminal of the first peripheral interface is electrically connected to the data terminal of the second peripheral interface via the data communication channel switching circuit corresponding to the first peripheral interface and the data communication channel switching circuit corresponding to the second peripheral interface.

In this example, the control strategy determination circuit may be configured to: and determining a channel switching control strategy of the data communication channel switching circuit according to the corresponding connection mode of the data terminal of the first external interface and the data terminal of the second external interface.

In this example, the data terminal includes a plurality of pins, the data terminal of the first peripheral interface corresponding to the pins of the data terminal of the second peripheral interface. The corresponding connection mode is a corresponding mode of a pin of the data terminal of the first external interface and a pin of the data terminal of the second external interface.

Taking fig. 8 as an example, pin "TX 1" in the data terminal of the first peripheral interface is connected to pin "TX 1" in the data terminal of the second peripheral interface via the channel of TX1, and the corresponding connection modes at this time are corresponding. If the pin "TX 1" in the data terminal of the first peripheral interface is connected to the TX2 channel, and the pin "TX 1" in the data terminal of the second peripheral interface is connected to the TX1 channel, the corresponding connection mode at this time is non-corresponding, and it is necessary to switch to the corresponding connection channel.

For example, as shown in fig. 8, the data terminal of the first peripheral interface and the data terminal of the second peripheral interface are the data terminal of the first peripheral interface, the preset position of the channel switch in the data communication channel switching circuit 235 is the position shown by the solid line in fig. 8, and as for the data terminal of the second peripheral interface, the preset position of the channel switch in the data communication channel switching circuit 235 is also the position shown by the solid line in fig. 8, at this time, the corresponding connection modes are corresponding, and the positions of the channel switches in the two data communication channel switching circuits 235 may be kept unchanged. If the preset position of the channel switch in the data communication channel switching circuit 235 for the data terminal of the first peripheral interface is the position shown by the solid line in fig. 8, and the preset position of the channel switch in the data communication channel switching circuit 235 for the data terminal of the second peripheral interface is also the position shown by the dotted line in fig. 8, the corresponding connection manner is not corresponding at this time, and the channel switch position in any data communication channel switching circuit 235 corresponding to the first peripheral interface or the second peripheral interface may be switched at this time.

In one example of the present disclosure, the interface state information includes data communication indication information, and the control policy determination circuit is configured to determine the channel switching control policy of the data communication channel switching circuit according to the device insertion direction indication information when the data communication indication information indicates that data communication is performed.

In this example, the data communication indication information is used to indicate that the peripheral device needs to perform data communication through the data communication channel provided by the mobile power supply 200.

The data communication indication information may be transmitted by the peripheral device. Specifically, after the peripheral device is connected to the peripheral interface 210 of the mobile power supply 200, the data communication indication information is sent to the control policy determination circuit through the CC1 or the CC2 pin of the peripheral interface 210, and after receiving the data communication indication information, the control policy determination circuit executes an operation of determining the channel switching control policy of the data communication channel switching circuit according to the device insertion direction indication information.

In another example, the data communication indication information is a trigger condition for the control policy determination circuit to perform an operation of determining the channel switching control policy of the data communication channel switching circuit according to the device insertion direction indication information, and the control policy determination circuit does not perform the operation of determining the channel switching control policy of the data communication channel switching circuit according to the device insertion direction indication information if the data communication indication information is not received.

In one example of the present disclosure, the interface state information may include power supply mode information. The power supply mode can include normal charge mode and quick charge mode, compares in normal charge mode, can provide bigger charging power for peripheral equipment under the quick charge mode, saves charge time, and then improves charge efficiency. For example, the charging voltage in the conventional charging mode is 5V, and the charging current is up to 1.5A. And the charging voltage in the fast charging mode may be 12V and the charging current may be 3A.

The power supply mode information may carry information characterizing the normal charging mode or information characterizing the fast charging mode. In one example, the power supply mode information carries charging voltage information and charging current information, which may be used to characterize the power supply mode. For example, when the charging voltage information carried by the power supply mode information is 5V and the charging current information is 1.5A, it may be determined that the power supply mode indicated by the power supply mode information is the normal charging mode. When the charging voltage information carried by the power supply mode information is 12V and the charging current information is 3A, it may be determined that the power supply mode indicated by the power supply mode information is the fast charging mode.

The control strategy determination circuit is configured to determine a voltage adjustment strategy based on the power supply state information and the power supply mode information. For example, if the charging status information is DFP and the power supply mode information indicates a fast charging mode, the control policy determination circuit determines that the voltage adjustment policy is to charge the peripheral device in the fast charging mode.

In one example of the present disclosure, the mobile power supply 200 supports the pd (power delivery) protocol. In this example, the mobile power supply 200 may charge the peripheral device in a fast charge mode.

In one example, the mobile power supply 200 may select a charging mode from a normal charging mode and a fast charging mode for charging. In another example, the mobile power supply 200 may charge in a fast charge mode by default.

In the fast charge mode, there may be multiple levels of charging voltage and charging current to charge. For example, the charging voltage may be 5V, 12V, and 20V, and the charging current may be 1.5A, 3A, and 5A. The peripheral device may negotiate with the mobile power supply to determine a charging voltage and a charging current of one level from among the charging voltage levels and the charging current levels to perform charging.

One implementation of fast charging is as follows: after the mobile power supply 200 is connected to the peripheral device through the peripheral interface 210, the peripheral device starts the PD device policy manager when starting the fast charging. The peripheral device modulates the message of the protocol layer into an FSK (binary Frequency Shift Keying) signal based on the PD protocol and couples the FSK signal to a bus power supply (such as V of type-c interface)_BUS) In the above, when the PD device policy manager monitors that an FSK signal is coupled to a dc level of the bus power supply, the PD device policy manager may decode the FSK signal to obtain a Capabilities Source message, and then analyze the Capabilities Source message based on the PD protocol to obtain a list pair of all voltages and currents supportable by the peripheral device, the peripheral device may select one voltage and current pair and send a Request message carrying the voltage and current pair to the mobile power supply 200, and the mobile power supply 200 receives the Request cancellation messageAnd then the voltage and the current corresponding to the voltage and the current can be output.

In one example of the present disclosure, the mobile power supply 200 may further include a housing, and at least two interface processing circuits 230, a control circuit 250, and a power supply circuit 270 are disposed inside the housing, and the housing may protect various components.

At least two peripheral interfaces 210 are embedded in the housing and are displayed so as to be easily visible to a user for convenient use of the peripheral interfaces 210. Where the location where the peripheral interface 210 is embedded in the housing may be specified.

In one example of the present disclosure, the at least two peripheral interfaces 210, the at least two sets of interface processing circuits 230, the control Circuit 250, and the power supply Circuit 270 are all integrated on a PCB (Printed Circuit Board). Other circuits and components in the mobile power supply 200 may also be integrated on the PCB.

Fig. 9 illustrates a block diagram of a power and communication system of an embodiment of the present disclosure.

As shown in fig. 9, the power supply and communication system includes a mobile power source, a first peripheral device, and a second peripheral device.

In embodiments of the present description, the mobile power supply may implement various operations and functions described above with respect to fig. 1-8. The first peripheral equipment is electrically connected with the mobile power supply through a first peripheral interface; the second external equipment is electrically connected with the mobile power supply through a second external interface; the mobile power supply supplies power to the first peripheral equipment through the first peripheral interface and supplies power to the second peripheral equipment through the second peripheral interface; and the mobile power supply provides a data transmission channel through the first peripheral interface and the second peripheral interface so as to enable data transmission between the first peripheral equipment and the second peripheral equipment.

In one example of the present description, the first peripheral device includes smart glasses using virtual reality technology, and the second peripheral device includes a master device for controlling the smart glasses.

FIG. 10 shows a flow diagram of a method for powering a peripheral device of an embodiment of the present disclosure.

The method is executed by a mobile power supply, the mobile power supply comprises a first external interface, a second external interface, a first interface processing circuit, a second interface processing circuit, a control circuit and a power circuit, the first external interface and the second external interface are both provided with data terminals and power terminals, the data terminals of the first external interface are electrically connected with the data terminals of the second external interface to establish a data transmission channel, and each group of interface processing circuits comprises a control strategy determining circuit and a voltage adjusting circuit.

As shown in fig. 10, at block 1010, after the peripheral device accesses the first peripheral interface and/or the second peripheral interface, interface state information of the accessed peripheral interface is obtained, where the interface state information includes power supply state information.

In one example, only if the first peripheral interface or the second peripheral interface is connected with a peripheral device, the mobile power supply can supply power to the accessed peripheral device. In another example, the first peripheral interface and the second peripheral interface are both connected with peripheral devices, and the mobile power source may supply power to the accessed peripheral devices, and may also provide a data communication channel for data transmission between the peripheral devices connected with the first peripheral interface and the peripheral devices connected with the second peripheral interface.

At block 1020, a voltage regulation strategy for the voltage regulation circuit is determined at the control strategy determination circuit based on the power supply status information.

At block 1030, at the control circuit, the voltage adjustment circuit is controlled to voltage adjust the voltage output by the power circuit according to a voltage adjustment strategy to utilize the adjusted voltage to power the peripheral device via the power supply terminal.

In one example of the present disclosure, the interface status information includes charging mode information, and the voltage adjustment strategy is determined from the power supply status information and the charging mode information.

In an example of the present disclosure, the data terminal of the first peripheral interface is further configured to output interface state information of the first peripheral interface, and the data terminal of the second peripheral interface is further configured to output interface state information of the second peripheral interface, where the interface state information includes power supply state information.

In one example of the present disclosure, the first peripheral interface and the second peripheral interface further include an interface status information terminal for outputting interface status information of the corresponding peripheral interface.

In an example of the present disclosure, each set of the interface processing circuits further includes a data communication channel switching circuit, and the data terminal of the first peripheral interface is electrically connected to the data terminal of the second peripheral interface via the data communication channel switching circuit corresponding to the first peripheral interface and the data communication channel switching circuit corresponding to the second peripheral interface; the method may further comprise: determining a channel switching control strategy of a data communication channel switching circuit at a control strategy determining circuit according to a corresponding connection mode of a data terminal of a first external interface and a data terminal of a second external interface; and at the control circuit, controlling the data communication channel switching circuit to perform data communication channel switching according to a channel switching control strategy so that the peripheral devices realize data communication via the respectively connected data terminals.

In an example of the present disclosure, each set of interface processing circuits may further include a data communication channel switching circuit, and the data terminal of the first peripheral interface is electrically connected to the data terminal of the second peripheral interface via the data communication channel switching circuit corresponding to the first peripheral interface and the data communication channel switching circuit corresponding to the second peripheral interface, where the interface state information may further include device insertion direction indication information, and the device insertion direction indication information is used to indicate an insertion direction of an interface connected to the peripheral interface with respect to the peripheral interface.

The method may further comprise: determining a channel switching control strategy of the data communication channel switching circuit at the control strategy determining circuit according to the device insertion direction indication information; at the control circuit, controlling the data communication channel switching circuit to perform data communication channel switching according to a channel switching control strategy; and responding to a data communication request initiated by the peripheral equipment, and realizing data communication between the peripheral equipment performing data communication through the switched data communication channel.

In one example of the present disclosure, the interface state information may further include data communication indication information, and the channel switching control policy is determined according to the device insertion direction indication information when the data communication indication information indicates that data communication is performed.

Embodiments of a mobile power supply and a method of supplying power to a peripheral device according to the present disclosure are described above with reference to fig. 1 to 10.

Each unit of the mobile power supply of the present disclosure may be implemented by hardware, or may be implemented by software, or a combination of hardware and software. The software implementation is taken as an example, and is formed by reading corresponding computer program instructions in the storage into the memory for operation through the processor of the device where the software implementation is located as a logical means. In the present disclosure, each unit of the portable power source can be realized by an electronic device, for example.

Fig. 11 shows a block diagram of an electronic device 1100 for implementing a method of powering a peripheral device of an embodiment of the disclosure.

As shown in fig. 11, electronic device 1100 may include at least one processor 1110, a memory (e.g., non-volatile storage) 1120, a memory 1130, and a communication interface 1140, and the at least one processor 1110, memory 1120, memory 1130, and communication interface 1140 may be connected together via a bus 1150. The at least one processor 1110 executes at least one computer-readable instruction (i.e., the elements described above as being implemented in software) stored or encoded in memory.

In one embodiment, computer-executable instructions are stored in the memory that, when executed, cause the at least one processor 1110 to: after the peripheral equipment is accessed to the first peripheral interface and/or the second peripheral interface, acquiring interface state information of the peripheral interface, wherein the interface state information comprises power supply state information; determining a voltage adjustment strategy of the voltage adjustment circuit at the control strategy determination circuit according to the power supply state information; and at the control circuit, controlling the voltage adjustment circuit to perform voltage adjustment on the voltage output by the power supply circuit according to the voltage adjustment strategy to utilize the adjusted voltage to supply power to the peripheral device via the power supply terminal.

It should be understood that the computer-executable instructions stored in the memory, when executed, cause the at least one processor 1110 to perform the various operations and functions described above in connection with fig. 1-10 in the various embodiments of the present disclosure.

According to one embodiment, a program product, such as a machine-readable medium, is provided. A machine-readable medium may have instructions (i.e., elements described above as being implemented in software) that, when executed by a machine, cause the machine to perform various operations and functions described above in connection with fig. 1-10 in various embodiments of the present disclosure.

Specifically, a system or apparatus may be provided which is provided with a readable storage medium on which software program code implementing the functions of any of the above embodiments is stored, and causes a computer or processor of the system or apparatus to read out and execute instructions stored in the readable storage medium.

In this case, the program code itself read from the readable medium can realize the functions of any of the above-described embodiments, and thus the machine-readable code and the readable storage medium storing the machine-readable code form part of the present invention.

Examples of the readable storage medium include floppy disks, hard disks, magneto-optical disks, optical disks (e.g., CD-ROMs, CD-R, CD-RWs, DVD-ROMs, DVD-RAMs, DVD-RWs), magnetic tapes, nonvolatile memory cards, and ROMs. Alternatively, the program code may be downloaded from a server computer or from the cloud via a communications network.

The foregoing description of specific embodiments of the present disclosure has been described. Other embodiments are within the scope of the following claims. In some cases, the actions or steps recited in the claims may be performed in a different order than in the embodiments and still achieve desirable results. In addition, the processes depicted in the accompanying figures do not necessarily require the particular order shown, or sequential order, to achieve desirable results. In some embodiments, multitasking and parallel processing may also be possible or may be advantageous.

Not all steps and elements in the above flows and system structure diagrams are necessary, and some steps or elements may be omitted according to actual needs. The execution order of the steps is not fixed, and can be determined as required. The apparatus structures described in the above embodiments may be physical structures or logical structures, that is, some units may be implemented by the same physical entity, or some units may be implemented by a plurality of physical entities, or some units may be implemented by some components in a plurality of independent devices.

The term "exemplary" used throughout this disclosure means "serving as an example, instance, or illustration," and does not mean "preferred" or "advantageous over other embodiments. The detailed description includes specific details for the purpose of providing an understanding of the described technology. However, the techniques may be practiced without these specific details. In some instances, well-known structures and devices are shown in block diagram form in order to avoid obscuring the concepts of the described embodiments.

Alternative embodiments of the present disclosure are described in detail with reference to the drawings, however, the embodiments of the present disclosure are not limited to the specific details in the embodiments, and various simple modifications may be made to the technical solutions of the embodiments of the present disclosure within the technical concept of the embodiments of the present disclosure, and the simple modifications all belong to the protective scope of the embodiments of the present disclosure.

The previous description of the disclosure is provided to enable any person skilled in the art to make or use the disclosure. Various modifications to the disclosure will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other variations without departing from the scope of the disclosure. Thus, the disclosure is not intended to be limited to the examples and designs described herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (4)

1. A mobile power supply, comprising:

the data transmission system comprises a first external interface and a second external interface, wherein the first external interface and the second external interface are both provided with data terminals and power terminals, and the data terminals of the first external interface are electrically connected with the data terminals of the second external interface to establish a data transmission channel;

the system comprises a first group of interface processing circuits and a second group of interface processing circuits, wherein each group of interface processing circuits comprises a control strategy determination circuit and a voltage regulation circuit;

a control circuit; and

a power supply circuit electrically connected to the voltage adjustment circuit,

the first group of interface processing circuits are respectively and electrically connected with the first peripheral interface and the control circuit, the second group of interface processing circuits are respectively and electrically connected with the second peripheral interface and the control circuit, and the control strategy determination circuit is configured to determine a voltage adjustment strategy of the voltage adjustment circuit according to the power supply state information of the corresponding peripheral interface, and

the control circuit is configured to: and controlling the voltage adjusting circuit to perform voltage adjustment on the voltage output by the power supply circuit according to the voltage adjusting strategy so as to utilize the adjusted voltage to supply power to peripheral equipment coupled with the peripheral interface through the power supply terminal.

2. The mobile power supply of claim 1, wherein the data terminal of the first peripheral interface is further configured to output interface status information of the first peripheral interface, and the data terminal of the second peripheral interface is further configured to output interface status information of the second peripheral interface, wherein the interface status information includes power supply status information;

the first peripheral interface and the second peripheral interface are also provided with interface state information terminals, the interface state information terminals are used for outputting interface state information corresponding to the peripheral interfaces, and the interface state information comprises power supply state information;

each group of interface processing circuits also comprises a data communication channel switching circuit, the data terminal of the first peripheral interface is electrically connected with the data terminal of the second peripheral interface through the data communication channel switching circuit corresponding to the first peripheral interface and the data communication channel switching circuit corresponding to the second peripheral interface,

wherein the control strategy determination circuit is configured to: determining a channel switching control strategy of the data communication channel switching circuit according to a corresponding connection mode of the data terminal of the first external interface and the data terminal of the second external interface; and

the control circuit is configured to control the data communication channel switching circuit to perform data communication channel switching according to the channel switching control strategy, so that peripheral equipment realizes data communication by establishing data transmission channels through the respectively connected data terminals;

each group of interface processing circuits also comprises a data communication channel switching circuit, the data terminal of the first peripheral interface is electrically connected with the data terminal of the second peripheral interface through the data communication channel switching circuit corresponding to the first peripheral interface and the data communication channel switching circuit corresponding to the second peripheral interface,

wherein the interface state information further includes device insertion direction indication information for indicating an insertion direction of an interface connected with the peripheral interface with respect to the peripheral interface,

the control strategy determination circuit is configured to: determining a channel switching control strategy of the data communication channel switching circuit according to the device insertion direction indication information, an

The control circuit is configured to control the data communication channel switching circuit to perform data communication channel switching according to the channel switching control strategy, so that peripheral equipment realizes data communication by establishing data transmission channels through the respectively connected data terminals;

the interface status information further includes data communication indication information, an

The control strategy determination circuit is configured to determine a channel switching control strategy of the data communication channel switching circuit according to the device insertion direction indication information when the data communication indication information indicates to perform data communication;

the first external interface and the second external interface are both type-c interfaces;

the interface state information further includes power supply mode information, and the control policy determination circuit is configured to determine the voltage adjustment policy from the power supply state information and the power supply mode information;

the mobile power supply supports a PD protocol;

the power supply circuit comprises a power supply conversion circuit used for providing a voltage specified in the mobile power supply;

the power circuit also comprises a battery circuit, and the battery circuit is used for storing energy and supplying power;

the control circuit is integrated as a component with at least one of the following circuits:

a control strategy determination circuit;

a voltage regulation circuit; and

a data communication channel switching circuit; and

also included is a housing, the first set of interface processing circuitry, the second set of interface processing circuitry, the control circuitry, and the power circuitry are disposed inside the housing, and the first peripheral interface and the second peripheral interface are embedded in the housing and exposed.

3. A power supply and communication system, characterized in that it comprises:

the mobile power supply of any one of claims 1-2;

a first peripheral device electrically connected to the mobile power supply via a first peripheral interface;

a second peripheral device electrically connected to the mobile power supply via a second peripheral interface;

the mobile power supply supplies power to the first peripheral equipment through the first peripheral interface and supplies power to the second peripheral equipment through the second peripheral interface; and

the mobile power supply provides a data transmission channel via the first peripheral interface and the second peripheral interface to enable data transmission between the first peripheral device and the second peripheral device.

4. The power and communication system of claim 3, wherein the first peripheral device comprises smart glasses using virtual reality technology and the second peripheral device comprises a master device for controlling the smart glasses.

Images