KR20220133069A - Mobile device, electronic device and electronic system - Google Patents

Abstract

Provided is an electronic device which stably transmits and receives data based on power line communication and wireless communication. The electronic device includes a first mobile device, and a second mobile device directly connected to the first mobile device through a power line. The second mobile device performs power line communication with the first mobile device through a power line during a first time interval, and performs wireless communication with an external device during a second time interval, wherein the first and second time intervals do not overlap with each other.

Description

MOBILE DEVICE, ELECTRONIC DEVICE AND ELECTRONIC SYSTEM

The present invention relates to mobile devices, electronic devices and electronic systems.

With the recent development of technology, communication may be performed between mobile devices. Mobile devices may transmit and receive data in various ways. That is, mobile devices may perform wired or wireless communication. For example, mobile devices may perform power line communication (PLC) via a power line. Also, mobile devices may perform wireless communication without being connected through a terminal.

An ear bud is a device that outputs sound from a wirelessly received source signal. These earbuds include, for example, a communication module such as a Bluetooth module to perform short-range wireless communication, and a battery for supplying driving power to the communication module. As a dedicated charging device for charging the battery of the earbuds, a charging case (eg, a cradle) of a type capable of charging the battery of the earbuds while storing the earbuds is widely used. Power line communication may be performed between the earbuds and the cradle. Meanwhile, the demand for stable data transmission and reception between the earbuds and the cradle is increasing.

SUMMARY The technical problem to be solved by the present invention is to provide an electronic device that stably transmits and receives data based on power line communication and wireless communication.

Another technical problem to be solved by the present invention is to provide a mobile device that stably transmits and receives data based on power line communication and wireless communication.

Another technical problem to be solved by the present invention is to provide an electronic system for stably transmitting and receiving data based on power line communication and wireless communication.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

According to some embodiments of the present invention, an electronic device includes a first mobile device and a second mobile device directly connected to the first mobile device through a power line, wherein the second mobile device includes: During power line communication with the first mobile device through the power line, and performing wireless communication with an external device during a second time period, the first and second time periods may not overlap each other. .

According to some embodiments of the present invention, an electronic device includes a first mobile device including a first battery, and a second mobile device including a second battery and directly connected to the first mobile device through a power line. wherein the second mobile device provides a first output signal to the external device during a first period and provides a first data signal to the first mobile device after the provision of the first output signal is completed, and in the first period A second output signal may be provided to the external device during a subsequent and second period greater than the first period, and a second data signal may be provided to the first mobile device after the provision of the second output signal is completed.

According to some embodiments of the present invention, a mobile device includes a wireless module for receiving an input signal from an external device, a converter for converting an input signal into a rectified voltage, a regulator for generating an output voltage by adjusting the rectified voltage, and an output voltage a battery charged based on and a PLC module generating a pogo voltage delivered to the power line based on the output voltage, wherein the PLC module performs power line communication through the power line during a first time period, and the wireless module may perform wireless communication with an external device in response to an input signal during the second time period, and the first and second time periods may not overlap each other.

An electronic system according to some embodiments of the present invention provides an earbud including a first battery and a cradle directly connected to the earbud through a power line, including a second battery, and charging the first battery , and a wireless charging pad disposed adjacent to the cradle and configured to charge a second battery, wherein the cradle provides an ASK signal generated using a voltage of the second battery to the wireless charging pad during a first time period, and , during the second time period, a pogo voltage including a data signal generated using the voltage of the second battery may be provided to the earbuds through the power line, and the first and second time periods may not overlap each other.

The details of other embodiments are included in the detailed description and drawings.

1 is a diagram for describing an electronic system according to some exemplary embodiments.
FIG. 2 is a block diagram of the electronic system of FIG. 1 ;
3 is a block diagram of an electronic system in accordance with some embodiments.
4 is a block diagram of an electronic device according to some embodiments.
5 is a ladder diagram illustrating an operation of an electronic system according to some embodiments.
6 is a graph for explaining a shape of a voltage over time according to some embodiments.
FIG. 7 is a graph for explaining the shape of the voltage in the first mode of FIG. 6 .
FIG. 8 is a graph for explaining the shape of the voltage in the second mode of FIG. 6 .
9 is a block diagram of signal transmission in an electronic system in accordance with some embodiments.
10 is a diagram for explaining the structure of a data signal and a response signal transmitted and received between mobile devices.
11 is a flowchart illustrating a method of operating an electronic system according to some embodiments.
12 is a flowchart illustrating an operating method of an electronic system according to some embodiments.
13 is a block diagram of an electronic system in accordance with some embodiments.
14 is a block diagram of an electronic system in accordance with some embodiments.
15 is a flowchart for explaining the operation of the electronic system of FIG. 14 .
16 is a diagram for describing an electronic system according to some embodiments.
17 is a block diagram of an electronic system in accordance with some embodiments.

Hereinafter, embodiments according to the technical spirit of the present invention will be described with reference to the accompanying drawings.

1 is a diagram for describing an electronic system according to some exemplary embodiments.

Referring to FIG. 1 , an electronic system 10 may include an electronic device 20 and a power transfer device 300 . Here, the electronic device 20 may include the first mobile device 100 and the second mobile device 200 . That is, the electronic device 20 may have a form in which the first mobile device 100 and the second mobile device 200 are combined.

In some embodiments, the first mobile device 100 may be a wireless earphone or an ear bud. That is, the first mobile device 100 may be an earbud that receives an electrical signal from an external electronic device and converts the electrical signal into sound. Here, the external electronic device and the first mobile device 100 may transmit/receive data through wireless communication. The first mobile device 100 may include two earbuds, that is, a pair of earbuds, but in the present invention, it is assumed that the first mobile device 100 has one earbud. However, the embodiment of the present invention is not limited thereto, and the number of the first mobile devices 100 is not limited thereto. The first mobile device 100 may be accommodated in the second mobile device 200 and charged.

In some embodiments, the second mobile device 200 may be a charging case or cradle. The second mobile device 200 may accommodate the first mobile device 100 to charge the first mobile device 100 . Also, the second mobile device 200 may be charged by receiving power from the outside, and may provide the charged power to the first mobile device 100 . The second mobile device 200 and the first mobile device 100 may be directly connected by wire, and the first mobile device 100 may be detachable from the second mobile device 200 . The first mobile device 100 and the second mobile device 200 may transmit/receive data through wired communication. The second mobile device 200 may check the state of the accepted first mobile device 100 through wired communication.

In some embodiments, the power transmission device 300 may be a wireless charging pad. The power transmitter 300 may be connected to an external power source to provide power to the second mobile device 200 . That is, the power transmitter 300 may convert external power into an electrical signal and provide the converted electrical signal to the second mobile device 200 . The second mobile device 200 may be charged using the converted electrical signal. When the second mobile device 200 is being charged, the second mobile device 200 and the power transmission device 300 may be in contact. However, the embodiment of the present invention is not limited thereto, and the second mobile device 200 and the power transmitter 300 may be spaced apart from each other by a predetermined distance. That is, the second mobile device 200 may be charged when it is disposed within a predetermined distance of the power transmission device 300 . Data may be transmitted/received through wired communication between the second mobile device 200 and the power transmitter 300 . Even when the first mobile device 100 is detached from the second mobile device 200 , the second mobile device 200 may be charged by the power transmission device 300 , and the second mobile device 200 Even when the first mobile device 100 is accommodated, the second mobile device 200 may be charged by the power transmission device 300 .

FIG. 2 is a block diagram of the electronic system of FIG. 1 ;

Referring to FIG. 2 , the electronic device 20 may be disposed to be spaced apart from the power transmission device 300 . That is, the electronic device 20 and the power transmitter 300 may not be electrically or directly connected through a terminal. The electronic device 20 and the power transmitter 300 may be in contact, but may not be electrically connected through a metal terminal. On the other hand, the first mobile device 100 and the second mobile device 200 may be directly connected through the power line POWL. That is, the first mobile device 100 and the second mobile device 200 may exchange electrical signals through the power line POWL. The power line POWL may connect the first connection terminal T1 of the first mobile device 100 and the second connection terminal T2 of the second mobile device 200 . Here, the first connection terminal T1 and the second connection terminal T2 may be POGO pins.

In some embodiments, the first mobile device 100 may include a control circuit 120 , a PLC module 130 , a charging circuit 140 , and a first battery BAT1 . The first mobile device 100 may further include an impedance element connected to the first connection terminal T1 , and the impedance element may include a circuit such as a resistor and/or a capacitor. A voltage swing or a current swing is transmitted through the power line POWL connected to the first connection terminal T1 so that data may be transmitted/received. Also, the swing level transmitted through the power line POWL may be adjusted according to the impedance value of the impedance element connected to the first connection terminal T1 .

The control circuit 120 may control the overall operation of the first mobile device 100 . For example, the control circuit 120 may control the PLC module 130 to control a communication operation with the second mobile device 200 . Also, the control circuit 120 may control the charging circuit 140 to charge the first battery BAT1 . In some embodiments, the control circuit 120 may include a micro control unit (MCU). However, the embodiment of the present invention is not limited thereto, and the control circuit 120 may include a processor or a central processing unit (CPU).

The PLC module 130 may receive power from the second mobile device 200 or transmit/receive data to and from the second mobile device 200 . The PLC module 130 may be controlled by the control circuit 120 . For example, the PLC module 130 may modulate the output current signal and output it through the first connection terminal T1 , and demodulate the input voltage signal received through the first connection terminal T1 to control circuitry. It can be forwarded to (120). For example, the PLC module 130 may include a current source, a current modulator, and a voltage modulator.

The charging circuit 140 may charge the first battery BAT1 using the power transmitted from the PLC module 130 . The charging circuit 140 may charge the first battery BAT1 under the control of the control circuit 120 . For example, when the first battery BAT1 is in a discharged state, the charging circuit 140 may charge the first battery BAT1 , and when the first battery BAT1 is in a fully charged state, charging The circuit 140 may not charge the first battery BAT1 . However, embodiments of the present invention are not limited thereto.

Here, the first mobile device 100 and the second mobile device 200 may transmit/receive power and data based on power line communication. For example, the first mobile device 100 may receive power from the second mobile device 200 or transmit/receive data to/from the second mobile device 200 through the first connection terminal T1 . For example, the second mobile device 200 may supply power to the first mobile device 100 or transmit/receive data to/from the first mobile device 100 through the second connection terminal T2 .

Power line communication is a communication technology that transmits power and data between devices over a power line (POWL). The power line POWL may be implemented through electrical contact between the first connection terminal T1 and the second connection terminal T2 , through which power and data may be transmitted. Accordingly, the first mobile device 100 may not include other connection terminals other than the first connection terminal T1 , and the second mobile device 200 may not include other connection terminals other than the second connection terminal T2 . it may not be That is, a separate connection terminal and a circuit connected thereto may be removed from the first mobile device 100 and the second mobile device 200 , and thus the size of the electronic device 20 may be reduced.

In some embodiments, the second mobile device 200 may include a wireless module 210 , a control circuit 220 , a PLC module 230 , and a second battery BAT2 . The second mobile device 200 may transmit/receive power or data to both the first mobile device 100 and the power transmitter 300 .

The wireless module 210 may perform wireless communication between the second mobile device 200 and the power transmitter 300 . That is, the wireless module 210 may receive the input signal IS from the power transmission device 300 , and transmit the output signal OS generated from the second mobile device 200 to the power transmission device 300 . can provide Here, the wireless module 210 may be paired with the wireless module 310 of the power transmission device 300 . In addition, the wireless module 210 may convert the input signal IS into a specific voltage or voltage signal, and may convert the specific voltage or voltage signal into an output signal OS. The wireless module 210 may provide a signal converted from the input signal IS to the control circuit 220 .

The control circuit 220 may control the wireless module 210 and the PLC module 230 . For example, the control circuit 220 may convert a voltage converted from the input signal IS from the wireless module 210 into a specific voltage and provide it to the PLC module 230 , and use the voltage to convert the second battery (BAT2) can be charged. That is, the control circuit 220 may control the wireless module 210 and the PLC module 230 in relation to power transmission and data transmission/reception. The control circuit 220 may be implemented substantially similarly to the control circuit 120 of the first mobile device 100 . In some embodiments, the control circuit 220 may include an MCU. However, the embodiment of the present invention is not limited thereto, and the control circuit 220 may include a processor or a CPU.

The PLC module 230 may transmit/receive data to and from the first mobile device 100 . For example, the PLC module 230 may modulate a voltage signal based on the voltage from the control circuit 220 and output it through the second connection terminal T2 and receive it through the second connection terminal T2 . One current signal may be demodulated and transmitted to the control circuit 220 . For example, the PLC module 230 may include a voltage modulator and a current modulator.

That is, the PLC module 130 of the first mobile device 100 and the PLC module 230 of the second mobile device 200 may transmit/receive data and transmit power through the power line POWL. That is, power transmission and data transmission/reception may be performed only through the power line POWL.

The power transmitter 300 may include an input voltage terminal Tin and a wireless module 310 . The input voltage terminal Tin may receive the input voltage Vin from the outside. The input voltage terminal Tin may receive the input voltage Vin from AC 110 to 220 V, which is a household power source, or other power supply means (eg, a computer or an auxiliary battery). The wireless module 310 may receive and process the input voltage Vin from the outside. For example, the wireless module 310 may generate the input signal IS based on the input voltage Vin, and may provide it to the second mobile device 200 . Here, the input signal IS may be a signal for transmitting power, and may include a signal to be transmitted to the electronic device 20 . Also, the output signal OS received by the wireless module 310 from the electronic device 20 may include a signal to be transmitted from the electronic device 20 to the power transmitter 300 . That is, the output signal OS may be a response signal to the input signal IS, and the input signal IS may be a response signal to the output signal OS. Communication between the power transmitter 300 and the electronic device 20 may be performed through wireless communication through the wireless module 210 and the wireless module 310 .

3 is a block diagram of an electronic system in accordance with some embodiments. 4 is a block diagram of an electronic device according to some embodiments. 5 is a ladder diagram illustrating an operation of an electronic system according to some embodiments.

3 and 5 , the second mobile device 200 may include a converter 221 , a regulator 222 , and a control module 223 . Here, the control circuit 220 described with reference to FIG. 2 may include a converter 221 , a regulator 222 , and a control module 223 . The control module 223 may control overall operations of the converter 221 , the regulator 222 , and the PLC module 230 .

The wireless module 310 of the power transmitter 300 may include a coil 311 , and the wireless module 210 of the second mobile device 200 may include a coil 211 . Here, the coil 311 and the coil 211 may correspond to each other. That is, the coil 311 and the coil 211 may transmit and receive signals by electromagnetic induction.

A voltage or current may be induced in the coil 211 by a change in voltage or current transmitted to the coil 311 , and an input signal IS may be transmitted from the wireless module 310 to the wireless module 210 . . A voltage or current may be induced in the coil 311 by a change in voltage or current transmitted to the coil 211 , and an output signal OS may be transmitted from the wireless module 210 to the wireless module 310 . .

For example, the power transmitter 300 may transmit power (S400). For example, a change in voltage or current may occur in the coil 311 of the wireless module 310 . Accordingly, the power transmitter 300 may provide the input signal IS to the second mobile device 200 (S401). As the input signal IS is transmitted to the second mobile device 200 , the wireless module 210 may generate a voltage signal by electromagnetic induction. Here, the input signal IS may include a frequency shift keying (FSK) signal generated by the power transmitter 300 . That is, the input signal IS may include an FSK data packet. The input signal IS may be a response to the output signal OS received from the second mobile device 200 , but the embodiment of the present invention is not limited thereto.

Subsequently, the second mobile device 200 may generate the rectified voltage VRECT and the output voltage VOUT, and may charge the second battery BAT2 ( S402 ). The converter 221 may convert a voltage signal from the wireless module 210 to generate a rectified voltage VRECT. That is, the converter 221 may include a rectifier for rectifying the voltage signal. The converter 221 may include a plurality of transistors and a plurality of passive elements, and may convert a voltage signal induced in the wireless module 210 to output a rectified voltage VRECT. Also, the converter 221 may be controlled by the control module 223 . Here, the rectified voltage VRECT may include a voltage signal, and the voltage signal may include a data signal from the power transmitter 300 .

The regulator 222 may generate the output voltage VOUT based on the rectified voltage VRECT output from the converter 221 . The regulator 222 may be controlled by the control module 223 . The regulator 222 may include a plurality of transistors and a plurality of passive elements, and may include an ESD prevention circuit. The regulator 222 may charge the second battery BAT2 based on the output voltage VOUT obtained by converting the rectified voltage VRECT. The regulator 222 and the second battery BAT2 may be directly connected. The regulator 222 may adjust a charging method for the second battery BAT2 according to the states of the power transmitter 300 and the first mobile device 100 . Through this, the second battery voltage VBAT2 may be applied to the second battery BAT2. The second battery BAT2 may be charged when a signal is transmitted from the power transmitter 300 to the second mobile device 200 . Also, the second battery BAT2 may be discharged as the first mobile device 100 is connected, and accordingly, the first battery BAT2 may be charged.

The second mobile device 200 may generate an output signal OS (S403). Also, the second mobile device 200 may provide the output signal OS to the power transmitter 300 . For example, the second mobile device 200 may generate the output signal OS by using the second battery voltage VBAT2 of the second battery BAT2 . Here, the output signal OS may include an amplitude shift keying (ASK) signal generated by the second mobile device 200 . That is, the output signal OS may include an ASK data packet. The output signal OS may be a response to the input signal IS received from the power transmitter 300 , but the embodiment of the present invention is not limited thereto. In summary, the second mobile device 200 may be charged by the power transmitter 300 and transmit/receive an input signal IS and an output signal OS to and from the power transmitter 300 . That is, the power transmitter 300 and the second mobile device 200 may transmit/receive an ASK signal and an FSK signal.

The PLC module 230 may include a voltage modulator V_MOD and a current demodulator I_DEM. For example, the PLC module 230 may be driven based on the output voltage VOUT. The PLC module 230 may be controlled by the control module 223 . The PLC module 230 may control the pogo voltage VPOGO and the pogo current IPOGO applied to the power line POWL. For example, the voltage modulator V_MOD may generate a pogo voltage VPOGO and provide it to the power line POWL, and the current demodulator I_DEM may receive data by demodulating the pogo current IPOGO. . The generated pogo voltage VPOGO may include a data signal. Also, the first mobile device 100 may be charged by the pogo voltage VPOGO transmitted to the power line POWL.

Referring to FIG. 4 , the PLC module 130 of the first mobile device 100 may include a current modulator I_MOD and a voltage demodulator V_DEM. The current modulator I_MOD may generate and provide the pogo current IPOGO to the power line POWL, and the voltage demodulator V_DEM may receive data by demodulating the pogo voltage VPOGO.

The control circuit 120 may process the demodulated pogo voltage VPOGO data to drive the charging circuit 140 . Also, the charging circuit 140 may charge the first battery BAT1 under the control of the control circuit 120 . That is, the charging circuit 140 may charge the first battery BAT1 based on the pogo voltage VPOGO. The first battery BAT1 may be charged with the first battery voltage VBAT1 .

The first mobile device 100 may be charged by the pogo voltage VPOGO transmitted by the power line POWL, and may receive data included in the pogo voltage VPOGO including a voltage swing. Also, the first mobile device 100 may provide data included therein by providing the pogo current IPOGO including the current swing to the second mobile device 200 through the power line POWL. That is, the first mobile device 100 and the second mobile device 200 may perform wired charging through the power line POWL and simultaneously perform power line communication.

Referring back to FIGS. 3 and 5 , the second mobile device 200 may perform an FSK check and a silent time (S405). That is, after transmitting the ASK signal to the power transmitter 300 , the second mobile device 200 may perform an FSK check. The second mobile device 200 may check that the FSK signal is transmitted from the power transmitter 300 in response to the ASK signal. However, the embodiment of the present invention is not limited thereto, and the FSK check operation may be omitted.

Subsequently, the second mobile device 200 may generate a pogo voltage VPOGO including the data signal DS ( S406 ). For example, the voltage modulator V_MOD of the PLC module 230 may generate the pogo voltage VPOGO based on the output voltage VOUT. The data signal DS may correspond to a swing of the generated pogo voltage VPOGO. That is, the operation of generating the pogo voltage VPOGO including the data signal DS may be performed after the ASK signal is transmitted.

Subsequently, the second mobile device 200 may provide the data signal DS to the first mobile device 100 ( S407 ). The transfer operation of the pogo voltage VPOGO including the data signal DS may be performed after the ASK signal is transmitted. That is, the time period in which the pogo voltage VPOGO including the data signal DS is transmitted may not overlap the time period in which the ASK signal is transmitted. For example, the time of wireless communication between the second mobile device 200 and the power transmitter 300 may not overlap with the time of wired communication between the second mobile device 200 and the first mobile device 100 . .

Subsequently, the second mobile device 200 may perform an ADC lead time ( S408 ). That is, after the second mobile device 200 applies the pogo voltage VPOGO including the data signal DS to the power line POWL, the second mobile device 200 may perform the ADC lead time. .

In summary, the second mobile device 200 may perform wireless communication and wired communication at different times. For example, a time during which an output signal OS including an ASK signal is transmitted from the second mobile device 200 to the power transmitter 300 may correspond to a wireless communication time period, and the second mobile device 200 ), a time during which the pogo voltage VPOGO including the data signal DS is transmitted to the first mobile device 100 may correspond to a wired communication time period. The wireless communication time interval and the wired communication time interval performed by the second mobile device 200 may not overlap each other, and accordingly, noise generated by performing the wireless communication may not affect the wired communication performance. . That is, since different types of communication operations are performed in different time intervals, noise generation may be reduced. Accordingly, the second mobile device 200 stably transmitting and receiving data based on power line communication and wireless communication may be provided.

6 is a graph for explaining a shape of a voltage over time according to some embodiments. FIG. 7 is a graph for explaining the shape of the voltage in the first mode of FIG. 6 . FIG. 8 is a graph for explaining the shape of the voltage in the second mode of FIG. 6 .

3 and 6 , the second mobile device 200 may operate in a first mode MOD1 and a second mode MOD2. Here, the first mode MOD1 may correspond to a time period in which a signal is transmitted from the power transmitter 300 to the second mobile device 200 , and the second mode MOD2 is from the power transmitter 300 . It may correspond to a time period after the signal is sufficiently transmitted to the second mobile device 200 . That is, the second mode MOD2 may correspond to a time period in which the second mobile device 200 and the power transmitter 300 are stabilized.

In the first mode MOD1 , the converter 221 of the second mobile device 200 may generate the rectified voltage VRECT, and the regulator 222 may generate the output voltage VOUT. That is, the rectified voltage VRECT generated by the voltage induced by the power transmitter 300 and the output voltage VOUT generated based on the rectified voltage VRECT appear. For example, the rectified voltage VRECT in the first mode MOD1 may be about 7V, and the output voltage VOUT may be about 5V. A voltage difference between the rectified voltage VRECT and the output voltage VOUT may be a first voltage difference DV1 . At the beginning of the first mode MOD1 , the rectified voltage VRECT may be greater than the output voltage VOUT. As time goes by, the rectified voltage VRECT may change to approximate the target rectified voltage VRECT_T. That is, the first voltage difference DV1 may decrease over time. The first voltage difference DV1 may be referred to as headroom.

In the second mode MOD2 , the converter 221 may generate the rectified voltage VRECT and the regulator 222 may generate the output voltage VOUT. For example, the rectified voltage VRECT in the second mode MOD2 may be about 6V, and the output voltage VOUT may be about 5V. That is, the rectified voltage VRECT in the second mode MOD2 may reach the target rectified voltage VRECT_T. A voltage difference between the rectified voltage VRECT and the output voltage VOUT may be a second voltage difference DV2 . The second voltage difference DV2 in the second mode MOD2 may be smaller than the first voltage difference DV1 . Accordingly, the headroom between the rectified voltage VRECT and the output voltage VOUT may be reduced. As the headroom between the rectified voltage VRECT and the output voltage VOUT decreases, the ASK signal may be induced to the power line POWL, and overlap between the ASK signal and the pogo voltage VPOGO may occur, resulting in noise. have.

According to an embodiment of the present invention, as the wireless communication operation and the power line communication operation are performed during different time intervals, even if the headroom between the rectified voltage VRECT and the output voltage VOUT decreases, the second mobile device 200 noise may not occur.

6 and 7 , in the first mode MOD1 , the first rectified voltage VRECT_1 may have a first ASK signal generation period T1 ′. That is, the first ASK signal included in the first rectified voltage VRECT_1 may be generated every first ASK signal generation period T1'. The first ASK signal may be expressed as a swing of the first rectified voltage VRECT_1 . Here, the first ASK signal may have an ASK packet length (xa). That is, the first ASK signal included in the first rectified voltage VRECT_1 may be provided from the second mobile device 200 to the power transmitter 300 for a time corresponding to the ASK packet length xa.

After the first ASK signal included in the first rectified voltage VRECT_1 is transmitted, an FSK check time xb may proceed, and then the first data signal included in the first pogo voltage VPOGO_1 may be transmitted . Here, the first data signal may be transmitted during the first PLC available time T_AVL_1. That is, the first data signal may be transmitted from the second mobile device 200 to the first mobile device 100 through the power line POWL during the first PLC available time T_AVL_1 . Here, the data packet length xd of the first data signal may be smaller than the first PLC available time T_AVL_1. Also, the ADC read time (xc) may be performed after the first PLC available time (T_AVL_1).

In some embodiments, the ASK packet length (xa) may correspond to operation S404 of FIG. 5, the FSK check time (xb) may correspond to operation S405 of FIG. 5, and the data packet length (xd) may correspond to operation S404 of FIG. It may correspond to operation S407, and the ADC read time xc may correspond to operation S408 of FIG. 5 . However, embodiments of the present invention are not limited thereto.

That is, a plurality of operations may be performed during the first ASK signal generation period T1 ′ in the first mode MOD1 . Here, the ASK packet length (xa) corresponding to the time when the ASK signal is transmitted through wireless communication and the first PLC available time (T_AVL_1) or the data packet length (xd) may not overlap each other. As the wireless communication operation and the power line communication operation by the second mobile device 200 are performed at different times, noise may be reduced.

In addition, the first ASK signal generation period T1' may be the sum of the ASK packet length xa, the FSK check time xb, the first PLC available time T_AVL_1, and the ADC read time xc. The second mobile device 200 calculates the first PLC available time T_AVL_1 that does not overlap with the ASK packet length xa within the first ASK signal generation period T1', and transmits the data signal during the time. can Thereafter, the operation of the second mobile device 200 may be repeated during the first mode MOD1 according to the first ASK signal generation period T1 ′.

6 and 8 , in the second mode MOD2, the second rectified voltage VRECT_2 may have a second ASK signal generation period T2'. That is, the second ASK signal included in the second rectified voltage VRECT_2 may be generated every second ASK signal generation period T2'. Here, the second ASK signal generation period T2' may be greater than the first ASK signal generation period T1'. That is, as time goes by, the second mobile device 200 may perform the second mode MOD2 from the first mode MOD1, and the ASK signal generation period may also increase. For example, the first ASK signal generation period T1' may be 80 ms, and the second ASK signal generation period T2' may be 128 ms.

In some embodiments, the ASK packet length (xa), FSK check time (xb), data packet length (xd), and ADC read time (xc) of FIG. 8 may be the same as the corresponding times of FIG. 7 . As the ASK signal generation period increases from the first ASK signal generation period T1' to the second ASK signal generation period T2', the second PLC available time T_AVL_2 may also increase. That is, the second PLC available time T_AVL_2 may be greater than the first PLC available time T_AVL_1 in the first mode MOD1 .

In the second mode MOD2, as the second ASK signal generation period T2' increases, the data packet transmission time may increase. That is, the second PLC available time T_AVL_2 calculated by the second mobile device 200 may increase, and the data packet may be transmitted within the second PLC available time T_AVL_2 .

9 is a block diagram of signal transmission in an electronic system in accordance with some embodiments.

Referring to FIG. 9 , the second mobile device 200 of the electronic system 10 may perform a wireless communication operation and a power line communication operation at different times. For example, the second mobile device 200 may provide the data signal DS to the first mobile device 100 during the first time period TP1, and during the second time period TP2, the output signal ( OS) may be provided to the power transmission device 300 . Here, the first time period TP1 may correspond to the first PLC available time T_AVL_1 or the second PLC available time T_AVL_2 described with reference to FIG. 7 , and the second time period TP2 is the ASK packet length ( xa) may apply. The first time period TP1 and the second time period TP2 do not overlap each other, and accordingly, noise of the electronic system 10 including the second mobile device 200 may be further reduced.

Although the communication operation between the second mobile device 200 and the first mobile device 100 and the communication operation between the second mobile device 200 and the power transmission device 300 are described as being performed at different times, the second mobile The charging operation of the device 200 and the first mobile device 100 may be performed simultaneously. That is, only the swing of the voltage or current transmitted to each mobile device may be performed in different time intervals.

10 is a diagram for explaining the structure of a data signal and a response signal transmitted and received between mobile devices.

Referring to FIG. 10 , a data signal DS may be transmitted/received from the second mobile device 200 based on a voltage swing or a current swing through the power line POWL. The data signal DS may include a plurality of fields. For example, the data signal DS may include a start field, a header type field, a header parity field, a data message field, a data parity field, a data checksum field, and an end field. Also, the data signal DS may include a preamble signal transmitted before data having a predetermined structure is transmitted.

The start field, the header type field, and the header parity field may correspond to header information, and the data message field, data parity field, data checksum field, and end field may correspond to data information. For example, the start field may have a value of 1 bit and may correspond to information indicating the start of data transmission. The header type field may include a plurality of bits and may indicate the type of transmitted data. The header parity field may have a value of 1 bit and may be used to determine the validity of transmitted header information.

Also, the data message field contains actual data having a plurality of bits. The data parity field may have a value of 1 bit to determine validity of data. The data checksum field may include a plurality of bits for error detection of data, and the end field may have a value of 1 bit to indicate the end of data transmission.

Meanwhile, the first mobile device 100 may provide the second mobile device 200 with an acknowledgment signal ACK for increasing the reliability of data transmission/reception. That is, the first mobile device 100 may provide the response signal ACK to the second mobile device 200 in response to the data signal DS. The response signal ACK may have a shorter field structure than the data signal DS. The acknowledgment signal ACK may include a start field, a header type field, and a header parity field. Also, the response signal ACK may include a preamble signal.

The start field has a value of 1 bit and may correspond to information indicating the start of transmission of the acknowledgment signal (ACK), and the header type field may include a plurality of bits and indicates the type of the acknowledgment signal (ACK) to be transmitted. The header parity field may include 1 bit and may be used to determine the validity of transmitted header information.

In the transmission/reception of the data signal DS and the response signal ACK, if the toggle exists within one period, it may correspond to a logic "1", and if the toggle does not exist, it may correspond to a logic "0". can

Hereinafter, an operating method of the electronic system 10 according to another exemplary embodiment will be described with reference to FIG. 11 .

11 is a flowchart illustrating a method of operating an electronic system according to some embodiments. For convenience of description, portions overlapping those described with reference to FIGS. 1 to 10 will be briefly described or omitted.

Referring to FIG. 11 , the electronic system 10 may charge the first mobile device 100 using the second mobile device 200 ( S410 ). That is, the electronic device 20 of the electronic system 10 may have a state in which the first mobile device 100 is accommodated in the second mobile device 200 . The first mobile device 100 may be charged by being directly connected to the second mobile device 200 through a power line POWL. In this case, the second battery BAT2 of the second mobile device 200 may be discharged over time, and the first battery BAT1 of the first mobile device 100 may be charged over time. can In this case, power line communication between the first mobile device 100 and the second mobile device 200 may be performed.

Subsequently, the second mobile device 200 and the power transmission device 300 may come into contact ( S411 ). For example, the electronic device 20 may contact the power transmission device 300 . However, the embodiment of the present invention is not limited thereto, and the electronic device 20 may be disposed to be spaced apart from the power transmission device 300 by a predetermined distance.

The electronic system 10 may charge the second mobile device 200 using the power transmission device 300 ( S412 ). Due to electromagnetic induction between the power transmitter 300 and the second mobile device 200 , the second battery BAT2 of the second mobile device 200 may be charged. That is, the second battery BAT2 and the first battery BAT1 may be simultaneously charged.

After the second mobile device 200 is charged by the power transmitter 300 , the second mobile device 200 may operate in the first mode MOD1 ( S413 ). 6 and 7 , the second mobile device 200 may output a first rectified voltage VRECT_1 having a first ASK signal generation period T1 ′ in a first mode MOD1 . In addition, the data packet using the power line communication may be transmitted during the first PLC available time (T_AVL_1).

Subsequently, after the first mode MOD1, the second mobile device 200 may operate in the second mode MOD2 (S414). 6 and 8 , the second mobile device 200 may output the second rectified voltage VRECT_2 having the second ASK signal generation period T2' in the second mode MOD2. In addition, the data packet using the power line communication may be transmitted during the second PLC available time (T_AVL_2).

That is, even when the electronic device 20 including the first mobile device 100 being charged by the second mobile device 200 is charged by the power transmission device 300, wirelessly in a time period that does not overlap with each other Communication and power line communication may be performed respectively.

Hereinafter, an operating method of the electronic system 10 according to another exemplary embodiment will be described with reference to FIG. 12 .

12 is a flowchart illustrating an operating method of an electronic system according to some embodiments. For convenience of description, portions overlapping with those described with reference to FIGS. 1 to 11 will be briefly described or omitted.

Referring to FIG. 12 , the electronic system 10 may charge the second mobile device 200 using the power transmission device 300 ( S420 ). That is, before the first mobile device 100 is connected to the second mobile device 200 , wireless charging may be performed on the second mobile device 200 by the power transmitter 300 . The second battery BAT2 of the second mobile device 200 may be being charged.

Subsequently, the first mobile device 100 may be accommodated in the second mobile device 200 ( S421 ). Also, the first mobile device 100 may be charged using the second mobile device 200 ( S422 ). The second mobile device 200 may be directly connected to the first mobile device 100 through a power line POWL, and may perform power line communication. That is, the first battery BAT2 of the first mobile device 100 may be charged using the second battery BAT2 of the second mobile device 200 . Also, the wireless communication between the second mobile device 200 and the power transmitter 300 may be performed at a different time from the power line communication between the second mobile device 200 and the first mobile device 100 .

Subsequently, the second mobile device 200 may operate in the first mode MOD1 ( S423 ). Subsequently, after the first mode MOD1, the second mobile device 200 may operate in the second mode MOD2 (S424).

Hereinafter, an electronic system 10b according to another embodiment will be described with reference to FIG. 13 .

13 is a block diagram of an electronic system in accordance with some embodiments. For convenience of description, portions overlapping those described with reference to FIGS. 1 to 12 will be briefly described or omitted.

Referring to FIG. 13 , the first mobile device 100 of the electronic system 10b may include a power management integrated circuit 150 , and the second mobile device 200 may include a power management integrated circuit 240 . can do. The power management integrated circuit 150 may manage the first battery BAT1 , and the power management integrated circuit 240 may manage the second battery BAT2 . In addition, the power management integrated circuit 150 and the power management integrated circuit 240 may control a current or voltage used for power line communication by the power line POWL. For example, the PLC module 130 may perform current modulation or voltage demodulation using power from the power management integrated circuit 150 , and the PLC module 230 may use power from the power management integrated circuit 240 . Voltage modulation or current demodulation may be performed using power.

The power management integrated circuit 150 may control a mode in which the first battery BAT1 is charged according to a connection with the second mobile device 200 , and the power management integrated circuit 240 may be configured to operate the first mobile device 100 . Alternatively, the mode in which the second battery BAT2 is charged may be controlled according to the connection with the power transmitter 300 .

Hereinafter, an electronic system 10c according to another exemplary embodiment will be described with reference to FIG. 14 .

14 is a block diagram of an electronic system in accordance with some embodiments. 15 is a flowchart for explaining the operation of the electronic system of FIG. 14 . For convenience of description, portions overlapping with those described with reference to FIGS. 1 to 13 will be briefly described or omitted.

Referring to FIG. 14 , the electronic system 10c may support both wireless charging and wired charging between the second mobile device 200 and the power transmitter 300 .

For example, the second mobile device 200 may include the wireless module 210 , the power transmission device 300 may also include the wireless module 310 , and the wireless module 210 and the wireless module 310 . Wireless charging of the second battery BAT2 may be performed by signal transmission between the .

At the same time, the second mobile device 200 may perform wired charging by the power transmission device 300 . For example, the second mobile device 200 may include a direct charging module 250 , and the power transmission device 300 may include a direct charging module 320 . Here, the direct charging module 250 and the direct charging module 320 may be directly connected through the third connection terminal T3 and the fourth connection terminal T4 . That is, the second mobile device 200 may receive power from the power transmitter 300 through a wire, and may charge the second battery BAT2 based thereon. Also, the second mobile device 200 may perform wired communication with the power transmitter 300 . That is, while the second mobile device 200 described with reference to FIGS. 1 to 13 performs wireless charging by the power transmitter 300 and performs wireless communication with the power transmitter 300 , FIG. 14 . The second mobile device 200 described with reference to may perform wired charging and wired communication as well as wireless charging and wireless communication.

Referring to FIG. 15 , the second mobile device 200 may determine whether it is wireless charging ( S430 ). When it is determined that the second mobile device 200 is wireless charging (S430-Y), for example, when the power transmission device 300 and the second mobile device 200 are not electrically connected, the second mobile The device 200 may be charged using the wireless module 210 (S431). Thereafter, the second mobile device 200 may operate in the first mode MOD1 ( S432 ), and then may operate in the second mode MOD2 ( S433 ).

When it is not determined that the second mobile device 200 is wireless charging (S430-N), for example, when the power transmission device 300 and the second mobile device 200 are electrically directly connected, the second The mobile device 200 may be charged using the direct charging module 250 (S434). That is, the second mobile device 200 may directly receive a voltage or current from the power transmitter 300 and may charge the second battery BAT2 using the voltage or current.

In this case, the second mobile device 200 may perform wired charging with respect to the first mobile device 100 at the same time as performing wired charging by the power transmission device 300 . Also, the second mobile device 200 may perform wired communication with the power transmitter 300 and may perform power line communication with the first mobile device 100 . Here, a time during which wired communication is performed between the second mobile device 200 and the power transmitter 300 may overlap with a time during which power line communication is performed between the second mobile device 200 and the first mobile device 100 . have. That is, the second mobile device 200 may simultaneously communicate with the power transmitter 300 and the first mobile device 100 , which may not generate noise.

However, when the second mobile device 200 performs wireless communication with the power transmitter 300 , the time period during which the wireless communication is performed is the time period during which the second mobile device 200 performs power with the first mobile device 100 . It may not overlap a time period for performing line communication.

Hereinafter, an electronic system 10d according to another exemplary embodiment will be described with reference to FIG. 16 .

16 is a diagram for describing an electronic system according to some embodiments. For convenience of description, portions overlapping with those described with reference to FIGS. 1 to 13 will be briefly described or omitted.

Referring to FIG. 16 , an electronic system 10d may include an electronic device 20 and a power transmitter 300 ′ that are spaced apart from each other. The electronic device 20 may be disposed to be spaced apart from the power transmission device 300 ′. That is, the electronic device 20 may not come into contact with the power transmission device 300 ′. That is, the power transmission device 300 ′ may correspond to a non-contact charging pad.

The electronic device 20 may receive an electrical signal emitted from the power transmission device 300 ′, and perform wireless charging based thereon. Also, the electronic device 20 may perform wireless communication with the power transmitter 300 ′. As the distance between the electronic device 20 and the power transmitter 300 ′ is changed, the ASK signal may be transmitted from the second mobile device 200 to the power transmitter 300 ′.

Hereinafter, an electronic system 10e according to another exemplary embodiment will be described with reference to FIG. 17 .

17 is a block diagram of an electronic system in accordance with some embodiments. For convenience of description, portions overlapping with those described with reference to FIGS. 1 to 13 will be briefly described or omitted.

Referring to FIG. 17 , the electronic system 10e may further include a main device 500 . Here, the main device 500 may include an electronic device such as a mobile phone, a PC, or a notebook computer. The main device 500 may include a module for performing wireless communication.

The first mobile device 100 may include a wireless communication module 160 . The wireless communication module 160 may be connected to the main device 500 to perform wireless communication. The wireless communication module 160 may receive data from the main device 500 , process and output the received data. Also, the wireless communication module 160 may provide data received from the main device 500 to the second mobile device 200 . That is, the first mobile device 100 and the second mobile device 200 may perform power line communication, and the first mobile device 100 and the main device 500 may perform wireless communication.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, the present invention is not limited to the above embodiments, but may be manufactured in various different forms, and those of ordinary skill in the art to which the present invention pertains. It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without changing the technical spirit or essential features of the present invention. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

10: electronic system 20: electronic device
100: first mobile device 200: second mobile device
210: wireless module 220: control circuit
230: PLC module 300: power transmission device

Claims (20)

a first mobile device; and
a second mobile device directly connected to the first mobile device through a power line;
The second mobile device,
perform power line communication with the first mobile device through the power line during a first time period;
Perform wireless communication with an external device during the second time period,
The first and second time intervals do not overlap each other. The method of claim 1,
The second mobile device provides an amplitude shift keying (ASK) signal to the external device during the second time period. The method of claim 1,
the second mobile device provides a POGO voltage to the power line during the first time period;
The first mobile device is charged using the pogo voltage. 4. The method of claim 3,
The pogo voltage includes a data signal transmitted through the power line communication,
The first mobile device generates a POGO current in response to the data signal. The method of claim 1,
The first mobile device includes a first battery,
The second mobile device includes a second battery,
The first battery is charged based on the pogo voltage generated by using the second battery,
The second battery is wirelessly charged based on a signal received from the external device. The method of claim 1,
The second mobile device receives a frequency shift keying (FSK) signal from the external device during a third time interval that does not overlap the first and second time intervals. The method of claim 1,
The second mobile device is an electronic device that simultaneously performs power line communication with the first mobile device and wired communication with the external device. The method of claim 1,
The first mobile device is an ear bud,
and the second mobile device is a cradle for accommodating the earbuds. a first mobile device comprising a first battery; and
A second mobile device including a second battery and directly connected to the first mobile device through a power line,
The second mobile device,
providing a first output signal to an external device during a first period and providing a first data signal to the first mobile device after providing of the first output signal is completed;
providing a second output signal to the external device for a second period subsequent to the first period and greater than the first period and providing a second data signal to the first mobile device after providing the second output signal is completed electronic device. 10. The method of claim 9,
The second mobile device provides first and second output signals to the external device through wireless communication and provides first and second data signals to the first mobile device through power line communication. 11. The method of claim 10,
The first and second output signals include an ASK signal. 10. The method of claim 9,
the second mobile device provides a pogo voltage including the first and second data signals to the first mobile device;
The first mobile device charges a first battery using the pogo voltage. 13. The method of claim 12,
and the first mobile device provides a pogo current to the power line in response to the first and second data signals. 10. The method of claim 9,
A first time interval for providing the first data signal is smaller than a second time interval for providing the second data signal. a wireless module for receiving an input signal from an external device;
a converter converting the input signal into a rectified voltage;
a regulator for generating an output voltage by regulating the rectified voltage;
a battery charged based on the output voltage; and
A PLC module for generating a pogo voltage transmitted to a power line based on the output voltage,
The PLC module performs power line communication through the power line for a first time period,
The wireless module performs wireless communication with the external device in response to the input signal during a second time period,
The first and second time intervals do not overlap each other. 16. The method of claim 15,
a difference between the rectified voltage and the output voltage decreases over time. 16. The method of claim 15,
The pogo voltage includes a data signal transmitted through the power line communication. 16. The method of claim 15,
The wireless module is a mobile device that provides an ASK signal to the external device. 16. The method of claim 15,
Further comprising a direct charging module directly connected to the external device,
The battery is charged by a signal received from the direct charging module,
A mobile device in which power line communication by the PLC module and wired communication by the direct charging module are simultaneously performed. 16. The method of claim 15,
The wireless module detects the FSK signal from the external device at a third time that does not overlap the first and second times.

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