CN116056049A - Fusion embedded unit and fusion terminal - Google Patents

Abstract

The application provides a fusion embedded unit and a fusion terminal, wherein the fusion embedded unit is applied to the fusion terminal and comprises a 5G module, a 2.4G downlink communication unit, an interface unit, an antenna unit and a control unit; the 5G module and the 2.4G downlink communication unit are respectively connected with the antenna unit; the first interface, the 5G module and the 2.4G downlink communication unit in the interface unit are respectively connected with the control unit, and the 5G module and the 2.4G downlink communication unit are respectively connected with the second interface in the interface unit. According to the method and the device, the intelligent fusion terminal does not need to be modified, so that the manufacturing cost is reduced; the intelligent fusion terminal has the capability of 5G communication and 2.4G wireless communication, and ensures the normal return of the power service data.

Description

Fusion embedded unit and fusion terminal

Technical Field

The application relates to the technical field of power systems, in particular to a fusion embedded unit and a fusion terminal.

Background

When a 5G (5 th-Generation Mobile Communication Technology, abbreviated as 5G) service terminal exists in the power system, the fusion terminal needs to be upgraded, so that the equipment needs to have the capability of 5G communication and 2.4G (2.4 GHz Wireless Technology, abbreviated as 2.4G) communication at the fusion terminal, and normal return of power service data is further ensured.

In the prior art, a 5G module and a 2.4G module are independently embedded into a fusion terminal; or the 5G module is vertically embedded into the fusion terminal, and the 2.4G module is integrated in a terminal main board, so that the equipment needs to have the capability of 5G communication and 2.4G communication at the fusion terminal.

However, in the above manner, when the 2.4G module is independently embedded in the fusion terminal, the power fusion terminal needs to be modified, which has the problems of complicated operation and high modification cost.

Disclosure of Invention

The application provides a fuse embedded unit and fuse terminal for solve because of needs reform transform electric power fuse terminal, there is complex operation, reform transform the problem with high costs.

In a first aspect, the present application provides a fusion embedded unit, where the fusion embedded unit is applied to a fusion terminal, and the fusion embedded unit includes a 5G module, a 2.4G downlink communication unit, an interface unit, an antenna unit, and a control unit; the 5G module and the 2.4G downlink communication unit are respectively connected with the antenna unit; the first interface, the 5G module and the 2.4G downlink communication unit in the interface unit are respectively connected with the control unit, and the 5G module and the 2.4G downlink communication unit are respectively connected with the second interface in the interface unit;

The control unit is used for acquiring first electric information received by the first interface from a main board in the fusion terminal, and sending the first electric information out through the 5G module or the 2.4G downlink communication unit; the first power information characterizes power business data sent by the power fusion terminal;

the 5G module is used for receiving second electricity utilization information through the antenna unit and sending the second electricity utilization information to a main board in the fusion terminal through the second interface; the second power consumption information represents power service data sent by the power service terminal;

the 2.4G downlink communication unit is configured to receive the second power consumption information through the antenna unit, and send the second power consumption information to a motherboard in the fusion terminal through the second interface.

In one example, the control unit is specifically configured to:

acquiring first electric information received by the first interface from a main board in the fusion terminal, and analyzing the first electric information to obtain protocol information;

if the protocol information is determined to characterize that the first electric information accords with the communication protocol corresponding to the 5G module, the first electric information is sent to a base station through the 5G module;

And if the protocol information is determined to characterize that the first electrical information accords with the communication protocol corresponding to the 2.4G downlink communication unit, transmitting the first electrical information to a downlink switch through the 2.4G downlink communication unit.

In one example, the control unit is further configured to:

and if the protocol information characterizes that the first electrical information does not accord with the communication protocol corresponding to the 5G module and does not accord with the communication protocol corresponding to the 2.4G downlink communication unit, determining that the first electrical information is not transmitted.

In one example, the antenna unit includes a first antenna and a second antenna, the 5G module is connected to the first antenna, and the 2.4G downlink communication unit is connected to the second antenna;

the 5G module is used for receiving second electricity utilization information through the first antenna and sending the second electricity utilization information to a main board in the fusion terminal through the second interface;

the 2.4G downlink communication unit is configured to receive the second power consumption information through the second antenna, and send the second power consumption information to a motherboard in the converged terminal through the second interface.

In one example, the first antenna is a 5G band antenna and the second antenna is a 2.4G band antenna.

In one example, the antenna unit further includes: a satellite antenna.

In one example, the fusion embedded unit is configured to enter a waiting mode after entering an initialization procedure; wherein the wait mode characterizes the converged embedded unit to initiate an internal sleep function.

In one example, the fusion embedded unit further includes an indicator light and a power source; the 5G module, the 2.4G downlink communication unit and the interface unit are respectively connected with the indicator lamp;

the power supply is used for providing electric energy for the fusion embedded unit;

and the indicator lamp is used for indicating the working state of the fusion embedded unit.

In one example, the 2.4G downstream communication unit includes a 2.4G micro control chip, a low noise amplifier, and a power amplifier; the low-noise amplifier and the power amplifier are respectively connected with the 2.4G micro-control chip;

the 2.4G micro-control chip is used for controlling the 2.4G downlink communication unit to enter a working mode or a dormant mode.

In one example, the 5G module includes a baseband chip, a power amplifier chip, a radio frequency chip, and a satellite positioning chip; the baseband chip and the power amplifier chip are respectively connected with the radio frequency chip;

The baseband chip is used for controlling the 5G module to enter a working mode or a dormant mode.

In a feasible implementation mode, for an intelligent fusion terminal of a power system, in order to upgrade the communication capability of the intelligent fusion terminal, a fusion embedded unit is arranged in the intelligent fusion terminal, the intelligent fusion terminal communicates with a service end and a base station through the fusion embedded unit, the fusion embedded unit comprises a 5G module, a 2.4G downlink communication unit, an interface unit, an antenna unit and a control unit, the 5G module is connected with the 2.4G downlink communication unit, and the 2.4G downlink communication unit is connected with the antenna unit; meanwhile, the interface unit comprises a first interface and a second interface, the first interface in the interface unit is connected with the control unit, the 5G module is connected with the control unit, the 2.4G downlink communication unit is connected with the control unit, the 5G module is connected with the second interface in the interface unit, and the 2.4G downlink communication unit is connected with the second interface in the interface unit; in the communication process of the fusion embedded unit, when the fusion embedded unit is in a transmission processing flow, the main board in the fusion terminal transmits power service data, the first interface in the interface unit receives the power service data transmitted by the fusion terminal, the control unit acquires the power service data from the first interface of the interface unit and transmits the power service data to the 5G module or the 2.4G downlink communication unit, and the 5G module or the 2.4G downlink communication unit transmits the received power service data to the base station or the power service terminal through the communication function of the 5G module or the 2.4G downlink communication unit; when the fusion embedded module is in the receiving processing flow, the 5G module can acquire the power business data from the antenna unit after the antenna unit receives the power business data sent by the power business terminal, and send the power business data to a main board in the fusion terminal through a second interface of the interface unit, so that remote communication is realized; the 2.4G downlink communication unit can acquire power service data from the antenna unit and send the power service data to a main board in the fusion terminal through a second interface of the interface unit to realize wireless data transmission; by arranging the 5G module and the 2.4G downlink communication unit in the fusion embedded unit, the intelligent fusion terminal does not need to be modified, so that the manufacturing cost is reduced; the intelligent fusion terminal has the capability of 5G communication and 2.4G wireless communication, and ensures the normal return of the power service data.

In a second aspect, the present application provides a fusion terminal, where the fusion terminal includes a motherboard and a fusion embedded unit as described in the first aspect;

the main board is connected with the fusion embedded unit.

In a feasible implementation mode, for the intelligent fusion terminal of the power system, in order to upgrade the communication capability of the intelligent fusion terminal, a main board and a fusion embedded unit are arranged in the intelligent fusion terminal, wherein one end of the main board is connected with one end of the fusion embedded unit, the main board of the intelligent fusion terminal can carry out 5G remote communication with a base station based on the fusion embedded unit, and meanwhile, the main board of the intelligent fusion terminal can carry out 2.4G frequency band micropower wireless communication with a downlink switch based on the fusion embedded unit, so that the fusion terminal does not need to be transformed, and the fusion terminal has the capability of 5G communication and 2.4G communication at the same time, and the information is rapidly acquired.

The fusion embedded unit is applied to the fusion terminal and comprises a 5G module, a 2.4G downlink communication unit, an interface unit, an antenna unit and a control unit; the 5G module and the 2.4G downlink communication unit are respectively connected with the antenna unit; the first interface, the 5G module and the 2.4G downlink communication unit in the interface unit are respectively connected with the control unit, and the 5G module and the 2.4G downlink communication unit are respectively connected with the second interface in the interface unit; the control unit is used for acquiring first electric information received by the first interface from a main board in the fusion terminal and sending the first electric information out through the 5G module or the 2.4G downlink communication unit; the first power information characterizes power business data sent by the power fusion terminal; the 5G module is used for receiving second electricity information through the antenna unit and sending the second electricity information to a main board in the fusion terminal through a second interface; the second power consumption information represents power service data sent by the power service terminal; and the 2.4G downlink communication unit is used for receiving the second electricity utilization information through the antenna unit and transmitting the second electricity utilization information to the main board in the fusion terminal through the second interface. Aiming at an intelligent fusion terminal of a power system, in order to upgrade the communication capability of the intelligent fusion terminal, a fusion embedded unit is arranged in the intelligent fusion terminal, the intelligent fusion terminal communicates with a service end and a base station through the fusion embedded unit, the fusion embedded unit comprises a 5G module, a 2.4G downlink communication unit, an interface unit, an antenna unit and a control unit, the 5G module is connected with the 2.4G downlink communication unit, and the 2.4G downlink communication unit is connected with the antenna unit; meanwhile, the interface unit comprises a first interface and a second interface, the first interface in the interface unit is connected with the control unit, the 5G module is connected with the control unit, the 2.4G downlink communication unit is connected with the control unit, the 5G module is connected with the second interface in the interface unit, and the 2.4G downlink communication unit is connected with the second interface in the interface unit; in the communication process of the fusion embedded unit, when the fusion embedded unit is in a transmission processing flow, the main board in the fusion terminal transmits power service data, the first interface in the interface unit receives the power service data transmitted by the fusion terminal, the control unit acquires the power service data from the first interface of the interface unit and transmits the power service data to the 5G module or the 2.4G downlink communication unit, and the 5G module or the 2.4G downlink communication unit transmits the received power service data to the base station or the power service terminal through the communication function of the 5G module or the 2.4G downlink communication unit; when the fusion embedded module is in the receiving processing flow, the 5G module can acquire the power business data from the antenna unit after the antenna unit receives the power business data sent by the power business terminal, and send the power business data to a main board in the fusion terminal through a second interface of the interface unit, so that remote communication is realized; the 2.4G downlink communication unit can acquire power service data from the antenna unit and send the power service data to a main board in the fusion terminal through a second interface of the interface unit to realize wireless data transmission; by arranging the 5G module and the 2.4G downlink communication unit in the fusion embedded unit, the intelligent fusion terminal does not need to be modified, so that the manufacturing cost is reduced; the intelligent fusion terminal has the capability of 5G communication and 2.4G wireless communication, and ensures the normal return of the power service data.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the application and together with the description, serve to explain the principles of the application.

Fig. 1 is a schematic structural diagram of a fusion terminal in the prior art;

fig. 2 is a schematic structural diagram of another fusion terminal in the prior art;

fig. 3 is a schematic structural diagram of a fusion embedded unit according to an embodiment of the present application;

fig. 4 is a schematic structural diagram of another fusion embedded unit according to an embodiment of the present application;

fig. 5 is a schematic structural diagram of a fusion terminal according to an embodiment of the present application;

fig. 6 is a block diagram of a converged terminal in accordance with an exemplary embodiment.

Specific embodiments thereof have been shown by way of example in the drawings and will herein be described in more detail. These drawings and the written description are not intended to limit the scope of the inventive concepts in any way, but to illustrate the concepts of the present application to those skilled in the art by reference to specific embodiments.

Detailed Description

Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, the same numbers in different drawings refer to the same or similar elements, unless otherwise indicated. The implementations described in the following exemplary examples are not representative of all implementations consistent with the present application. Rather, they are merely examples of apparatus and methods consistent with some aspects of the present application as detailed in the accompanying claims.

The power system relates to six links of power generation, power transmission, power transformation, power distribution, power consumption and scheduling, and has various power services such as power distribution automation, power consumption information acquisition, intelligent inspection, accurate load control and the like, and the requirements of various power services on the aspects of data flow direction, bandwidth, concurrency, time delay, power consumption and the like are greatly different. When a 5G (5 th-Generation Mobile Communication Technology, abbreviated as 5G) service terminal exists in the power system, the fusion terminal needs to be upgraded, so that the equipment needs to have the capability of 5G communication and 2.4G (2.4 GHz Wireless Technology, abbreviated as 2.4G) communication at the fusion terminal, and normal return of power service data is further ensured.

At present, a 5G module and a 2.4G module are independently embedded into a fusion terminal; or the 5G module is independently embedded into the fusion terminal, and the 2.4G module is integrated in a main board of the fusion terminal, so that the device needs to have the capability of 5G communication and 2.4G communication at the same time in the fusion terminal.

In one example, fig. 1 is a schematic structural diagram of a fusion terminal in the prior art, and as shown in fig. 1, a fusion terminal 10 includes a main board 11, a 5G independent embedded module 12 and a 2.4G independent embedded module 13, where the main board 11 is connected to the 5G independent embedded module 12 and the 2.4G independent embedded module 13, and the main board 11 and a base station are in communication through the 5G independent embedded module 12; the main board 11 and the downlink switch communicate through the 2.4G independent embedded module 13, so that the fusion terminal 10 has the capability of 5G communication and 2.4G communication.

In another example, fig. 2 is a schematic structural diagram of another fusion terminal in the prior art, as shown in fig. 2, the fusion terminal 20 includes a main board 21 and a 5G independent embedded module 22, a 2.4G independent embedded module 211 is disposed in the main board 21, the main board 21 is connected with the 5G independent embedded module 22, and the main board 11 and the base station are communicated through the 5G independent embedded module 22; the main board 11 communicates with the downlink switch through the 2.4G independent embedded module 211, so that the convergence terminal 20 has the capability of 5G communication and 2.4G communication at the same time

However, in the above manner, when the 2.4G module is independently embedded in the converged terminal, if the downlink device has other communication requirements, the embedded module needs to be replaced; in addition, when the 2.4G module is integrated in the main board of the fusion terminal, the fusion terminal which is not integrated with 2.4G does not support 2.4G communication, and the power fusion terminal needs to be modified, so that the cost is high.

The application provides a fusion embedded unit and a fusion terminal, which aim to solve the technical problems in the prior art.

The following describes the technical solutions of the present application and how the technical solutions of the present application solve the above technical problems in detail with specific embodiments. The following embodiments may be combined with each other, and the same or similar concepts or processes may not be described in detail in some embodiments. Embodiments of the present application will be described below with reference to the accompanying drawings.

Fig. 3 is a schematic structural diagram of a fusion embedded unit provided in the embodiment of the present application, as shown in fig. 3, the fusion embedded unit 300 is applied to a fusion terminal, and the fusion embedded unit 300 includes a 5G module 301, a 2.4G downlink communication unit 302, an interface unit 303, an antenna unit 304, and a control unit 305; the 5G module 301 and the 2.4G downlink communication unit 302 are respectively connected with the antenna unit 304; the first interfaces 3031, the 5G modules 301, and the 2.4G downlink communication units 302 in the interface unit 303 are respectively connected to the control unit 305, and the 5G modules 301, and the 2.4G downlink communication units 302 are respectively connected to the second interfaces 3032 in the interface unit 303.

The control unit 305 is configured to obtain first electrical information received by the first interface 3031 from a motherboard in the fusion terminal, and send the first electrical information through the 5G module 301 or the 2.4G downlink communication unit 302; the first power information characterizes power business data sent by the power fusion terminal.

The 5G module 301 is configured to receive the second electricity consumption information through the antenna unit 304, and send the second electricity consumption information to a motherboard in the fusion terminal through the second interface 3032; the second power consumption information represents power service data sent by the power service terminal.

The 2.4G downlink communication unit 302 is configured to receive the second power consumption information through the antenna unit 304, and send the second power consumption information to the motherboard in the converged terminal through the second interface 3032.

For example, for an intelligent fusion terminal of a power system, in order to upgrade a communication capability of the intelligent fusion terminal, a fusion embedded unit 300 is set in the intelligent fusion terminal, the intelligent fusion terminal communicates with a service end and a base station through the fusion embedded unit 300, the fusion embedded unit 300 includes a 5G module 301, a 2.4G downlink communication unit 302, an interface unit 303, an antenna unit 304, and a control unit 305,5G, the module 301 is connected with the 2.4G downlink communication unit 302, and the 2.4G downlink communication unit 302 is connected with the antenna unit 304; meanwhile, the interface unit 303 includes a first interface 3031 and a second interface 3032, the first interface 3031 in the interface unit 303 is connected to the control unit 305, the 5G module 301 is connected to the control unit 305, the 2.4G downlink communication unit 302 is connected to the control unit 305, the 5G module 301 is connected to the second interface 3032 in the interface unit 303, and the 2.4G downlink communication unit 302 is connected to the second interface 3032 in the interface unit 303.

In the communication process of the fusion embedded unit 300, the main board in the fusion terminal sends power service data, namely first electrical information, when the fusion embedded unit 300 is in a sending process flow, the first interface 3031 in the interface unit 303 receives the power service data sent by the fusion terminal, the control unit 305 obtains the power service data from the first interface 3031 in the interface unit 303 and sends the power service data to the 5G module 301 or the 2.4G downlink communication unit 302, and the 5G module 301 or the 2.4G downlink communication unit 302 sends the received power service data to the base station or the power service terminal through the communication function of the 5G module 301 or the 2.4G downlink communication unit 302.

When the antenna unit 304 receives the power service data sent by the power service terminal, namely the second power consumption information, and the fusion embedded unit 300 is in the process of accepting, the 5G module 301 may acquire the power service data from the antenna unit 304, and send the power service data to the motherboard in the fusion terminal through the second interface 3032 of the interface unit 303, so as to realize remote communication; the 2.4G downlink communication unit 302 may obtain power service data from the antenna unit 304, and send the power service data to the motherboard in the convergence terminal through the second interface 3032 of the interface unit 303, so as to implement wireless data transmission.

In this embodiment, the fusion embedded unit 300 is applied to a fusion terminal, and the fusion embedded unit 300 includes a 5G module 301, a 2.4G downlink communication unit 302, an interface unit 303, an antenna unit 304, and a control unit 305; the 5G module 301 and the 2.4G downlink communication unit 302 are respectively connected with the antenna unit 304; the first interfaces 3031, the 5G modules 301 and the 2.4G downlink communication units 302 in the interface unit 303 are respectively connected with the control unit 305, and the 5G modules 301 and the 2.4G downlink communication units 302 are respectively connected with the second interfaces 3032 in the interface unit 303; the control unit 305 is configured to obtain first electrical information received by the first interface 3031 from a motherboard in the fusion terminal, and send the first electrical information through the 5G module 301 or the 2.4G downlink communication unit 302; the first power information characterizes power business data sent by the power fusion terminal; the 5G module 301 is configured to receive the second electricity consumption information through the antenna unit 304, and send the second electricity consumption information to a motherboard in the fusion terminal through the second interface 3032; the second power consumption information represents power service data sent by the power service terminal; the 2.4G downlink communication unit 302 is configured to receive the second power consumption information through the antenna unit 304, and send the second power consumption information to the motherboard in the converged terminal through the second interface 3032. By arranging the 5G module 301 and the 2.4G downlink communication unit 302 in the fusion embedded unit 300, the fusion terminal does not need to be modified, so that the manufacturing cost is reduced; the fusion terminal has the capability of 5G communication and 2.4G wireless communication, and ensures the normal return of the power service data.

Fig. 4 is a schematic structural diagram of another fusion embedded unit provided in the embodiment of the present application, as shown in fig. 4, in which, the fusion embedded unit 400 is applied to a fusion terminal, and the fusion embedded unit 400 includes a 5G module 401, a 2.4G downlink communication unit 402, an interface unit 403, an antenna unit 404, and a control unit 405; the 5G module 401 and the 2.4G downlink communication unit 402 are respectively connected with the antenna unit 304; the first interface 4031 in the interface unit 403, the 5G module 401, and the 2.4G downlink communication unit 402 are respectively connected to the control unit 405, and the 5G module 401 and the 2.4G downlink communication unit 402 are respectively connected to the second interface 4032 in the interface unit 403.

The control unit 405 is configured to obtain first electrical information received by the first interface 4031 from the motherboard in the fusion terminal, and send the first electrical information out through the 5G module 401 or the 2.4G downlink communication unit 402; the first power information characterizes power business data sent by the power fusion terminal.

The 5G module 401 is configured to receive the second power consumption information through the antenna unit 404, and send the second power consumption information to the motherboard in the fusion terminal through the second interface 4032; the second power consumption information represents power service data sent by the power service terminal.

A 2.4G downlink communication unit 402, configured to receive the second power consumption information through an antenna unit 404, and send the second power consumption information to the motherboard in the converged terminal through a second interface 4032.

In one example, the control unit 405 is specifically configured to:

the first interface 4031 obtains the first electrical information received from the motherboard in the fusion terminal, and analyzes the first electrical information to obtain protocol information.

If it is determined that the protocol information characterizes that the first electrical information accords with the communication protocol corresponding to the 5G module 401, the first electrical information is sent to the base station through the 5G module 401.

If it is determined that the protocol information characterizes that the first electrical information accords with the communication protocol corresponding to the 2.4G downlink communication unit 402, the first electrical information is sent to the downlink switch through the 2.4G downlink communication unit 402.

In one example, the control unit 405 is further configured to:

if it is determined that the protocol information characterizes that the first electrical information does not conform to the communication protocol corresponding to the 5G module 401 and does not conform to the communication protocol corresponding to the 2.4G downlink communication unit 402, it is determined that the first electrical information is not transmitted.

In one example, the antenna unit 404 includes a first antenna 4041 and a second antenna 4042,5G module 401 coupled to the first antenna 4041 and the 2.4G downlink communication unit 402 coupled to the second antenna 4042.

The 5G module 401 is configured to receive the second electricity consumption information through the first antenna 4041, and send the second electricity consumption information to the motherboard in the fusion terminal through the second interface 4032.

The 2.4G downlink communication unit 402 is configured to receive the second power consumption information through the second antenna 4042, and send the second power consumption information to the motherboard in the converged terminal through the second interface 4032.

In one example, the first antenna 4041 is a 5G band antenna and the second antenna 4042 is a 2.4G band antenna.

In one example, the antenna unit 404 further includes: satellite antenna 4043.

In one example, the fusion embedded unit 400 is configured to enter a waiting mode after entering an initialization procedure; wherein the wait mode characterization fusion embedded unit 400 initiates an internal sleep function.

In one example, the fusion embedded unit 400 further includes an indicator light 406 and a power supply 407; the 5G module 401, the 2.4G downlink communication unit 402, and the interface unit 403 are respectively connected to the indicator light 407.

A power supply 406 for providing power to the fusion embedded unit 400.

The indicator light 407 is used for indicating the working state of the fusion embedded unit 400.

In one example, the 2.4G downstream communication unit 402 includes a 2.4G micro control chip 4021, a low noise amplifier 4022, and a power amplifier 4023; the low noise amplifier 4022 and the power amplifier 4023 are respectively connected with the 2.4G micro-control chip 4021.

The 2.4G micro control chip 4021 is configured to control the 2.4G downlink communication unit 402 to enter an operation mode or a sleep mode.

In one example, the 5G module 401 includes a baseband chip 4011, a power amplifier chip 4012, a radio frequency chip 4013, and a satellite positioning chip 4014; the baseband chip 4011 and the power amplifier chip 4012 are respectively connected with the radio frequency chip 4013;

and the baseband chip is used for controlling the 5G module to enter a working mode or a dormant mode.

Illustratively, a fusion embedded unit 400 is provided in an intelligent fusion terminal, the intelligent fusion terminal communicates with a service end and a base station through the fusion embedded unit 400, the fusion embedded unit 400 includes a 5G module 401, a 2.4G downlink communication unit 402, an interface unit 403, an antenna unit 404, and a control unit 405,5G, the module 401 is connected with the 2.4G downlink communication unit 402, and the 2.4G downlink communication unit 402 is connected with the antenna unit 404; meanwhile, the interface unit 403 includes a first interface 4031 and a second interface 4032, the first interface 4031 in the interface unit 403 is connected with the control unit 405, the 5G module 401 is connected with the control unit 405, the 2.4G downlink communication unit 402 is connected with the control unit 405, the 5G module 401 is connected with the second interface 4032 in the interface unit 403, and the 2.4G downlink communication unit 402 is connected with the second interface 4032 in the interface unit 403.

The main board in the convergence terminal will send power service data, the first interface 4031 in the interface unit 403 will accept the power service data sent by the convergence terminal, i.e. the first power information, the control unit 405 obtains the power service data from the first interface 4031 in the interface unit 403, and sends the power service data to the 5G module 401 or the 2.4G downlink communication unit 402, and the 5G module 401 or the 2.4G downlink communication unit 402 sends the received power service data to the base station or the power service end through the communication function of the 5G module 401 or the 2.4G downlink communication unit 402; the antenna unit 404 receives the power service data sent by the power service terminal, namely the second power consumption information, and the 5G module 401 can acquire the power service data from the antenna unit 404 and send the power service data to the main board in the fusion terminal through the second interface 4032 of the interface unit 403, so as to realize remote communication; the 2.4G downlink communication unit 402 may obtain power service data from the antenna unit 404, and send the power service data to the motherboard in the convergence terminal through the second interface 4032 of the interface unit 403, so as to implement wireless data transmission.

In an exemplary operation process of the convergence embedded unit 400, the motherboard in the convergence terminal will send power service data, the first interface 4031 in the interface unit 403 will accept the power service data sent by the convergence terminal, i.e. the first power information, the control unit 405 obtains the power service data from the first interface 4031 of the interface unit 403, analyzes the power service data to obtain corresponding communication protocol information, identifies the communication protocol information, if it is determined that the power service data accords with the communication protocol corresponding to the 5G module 401, the control unit 405 sends the corresponding power service data to the 5G module 401 for processing, and the 5G module 401 sends the received power service data to the base station again; if it is determined that the power service data conforms to the communication protocol corresponding to the 2.4G downlink communication unit 402, the control unit 405 sends the corresponding power service data to the 2.4G downlink communication unit 402 for processing, and the 2.4G downlink communication unit 402 resends the received power service data to the downlink switch.

In one example, during the operation of the fusion embedded unit 400, the fusion embedded unit 400 includes a 5G module 401 and a 2.4G downlink communication unit 402, where the 5G module 401 is based on a domestic chip 510 design technology, such as a sijiu fecund chip, and a domestic 5G communication module is adopted, so that data is safer, autonomous and controllable, and table 1 is a domestic 5G communication module performance parameter table, and its related performance is shown in table 1 below.

TABLE 1 domestic 5G communication Module Performance parameter Table

The wireless module used is DL-BK24C, which is a small-sized, low-cost and long-distance 2.4G wireless serial port module, the transmitting power is 12dBm, the unobstructed transmitting and receiving distance can reach 100 meters, when the first interface 4031 in the interface unit 403 receives the power service data sent by the fusion terminal, namely the first power information, the fusion embedded unit 400 enters the sending process flow, the control unit 405 obtains the power service data from the first interface 4031 of the interface unit 403, analyzes the power service data to obtain the corresponding communication protocol information, identifies the communication protocol information, if the power service data is determined to conform to the communication protocol corresponding to the 5G module 401, the control unit 405 sends the corresponding power service data to the 5G module 401 for processing, and the 5G module 401 resends the received power service data to the base station; if it is determined that the power service data conforms to the communication protocol corresponding to the 2.4G downlink communication unit 402, the control unit 405 sends the corresponding power service data to the 2.4G downlink communication unit 402 for processing, and the 2.4G downlink communication unit 402 resends the received power service data to the downlink switch or the sensor.

For example, if the control unit 405 analyzes the protocol, and if it is determined that the received power service data does not conform to the communication protocol corresponding to the 5G module 401 and does not conform to the communication protocol corresponding to the 2.4G downlink communication unit 402, the fusion embedded module is controlled to not process the power service data, and wait for receiving the next power service data.

Illustratively, during operation of the fusion embedded unit 400, the fusion embedded unit 400 further includes a 5G module 401 and a 2.4G downlink communication unit 402, and further includes an antenna unit 404, where one end of the antenna unit 404 including a first antenna 4041 and a second antenna 4042,5G module 401 is connected to one end of the first antenna 4041, and one end of the second antenna 4042 is connected to one end of the 2.4G downlink communication unit 402.

When the first antenna 4041 or the second antenna 4042 in the antenna unit 404 receives the power service data sent by the power service terminal, that is, the second power consumption information, the fusion embedded module is in an accepting process flow, when the first antenna 4041 in the antenna unit 404 receives the power service data, the 5G module 401 can acquire the power service data from the first antenna 4041 in the antenna unit 404, and send the power service data to the main board in the fusion terminal through the second interface 4032 of the interface unit 403, so as to realize remote communication; the 2.4G downlink communication unit 402 may obtain the power service data from the second antenna 4042 of the antenna unit 404 when the second antenna 4042 of the antenna unit 404 receives the power service data, and send the power service data to the motherboard in the convergence terminal through the second interface 4032 of the interface unit 403, so as to implement wireless data transmission.

Further, the first antenna 4041 is a 5G band antenna, and the second antenna 4042 is a 2.4G band antenna, where the 5G band antenna may support a 5G operating band and is compatible with part of 4G band and 3G band operation.

In one example, when the 5G band antenna of the antenna unit 404 receives the power service data from the base station, the 5G module 401 may obtain the power service data from the 5G band antenna of the antenna unit 404, and send the power service data to the motherboard in the convergence terminal through the second interface 4032 of the interface unit 403, so as to implement 5G remote communication between the convergence terminal and the base station.

In another example, when the 2.4G band antenna of the antenna unit 404 receives the power service data from the downlink intelligent switch, the 2.4G downlink communication unit 402 may obtain the power service data from the 2.4G band antenna of the antenna unit 404, and send the power service data to the motherboard in the convergence terminal through the second interface 4032 of the interface unit 403, so as to implement wireless data transmission between the convergence terminal and the downlink intelligent switch.

Illustratively, in the fusion embedded unit 400, the antenna unit 404 further comprises: satellite antenna 4043; the satellite antenna 4043 is used for receiving satellite signals.

Illustratively, an initialization program is built in the fusion embedded unit 400, after the power is turned on, each hardware inside the fusion embedded unit 400 is automatically initialized, and after the fusion embedded unit 400 enters the initialization program, a waiting mode is automatically performed, that is, the fusion embedded unit 400 starts an internal dormancy function, so as to reduce power consumption.

Further, in the fusion embedded unit 400, the fusion embedded unit comprises a 5G module 401, a 2.4G downlink communication unit 402, an interface unit 403, an indicator 406, and a power source 407,5G, wherein one end of each of the 2.4G downlink communication unit 402 and the interface unit 403 is respectively connected with one end of the indicator 406, and the power source 407 provides electric energy for the fusion embedded unit 400 during the communication operation of the fusion embedded unit 400.

When the indicator light 406 indicates that the working state of the fusion embedded unit 400 is the 5G mode, the indicator light 406 indicates that the 5G module 401 in the fusion embedded unit 400 is performing communication work, and the 2.4G downlink communication unit 402 in the fusion embedded unit 400 is in the standby mode; when the indicator light 406 indicates that the working state of the fusion embedded unit 400 is the 2.4G mode, the indicator light 406 indicates that the 2.4G downlink communication unit 402 in the fusion embedded unit 400 is performing communication, and the 5G module 401 in the fusion embedded unit 400 is in the standby mode.

In one example, in the fusion embedded unit 400, an indicator light 406 and one end of each of the power 407,5G module 401, the 2.4G downlink communication unit 402, and the interface unit 403 are respectively connected to one end of the indicator light 406. During the communication operation of the fusion embedded unit 400, the power supply 407 provides power for the fusion embedded unit 400, and when the indicator light 406 indicates that the operation state of the fusion embedded unit 400 is in the 5G mode, for example, the indicator light 406 lights up a green light, and at this time, the indicator light 406 indicates that the 5G module 401 in the fusion embedded unit 400 is in the communication operation, and the 2.4G downlink communication unit 402 in the fusion embedded unit 400 is in the standby mode; when the indicator light 406 indicates that the working state of the fusion embedded unit 400 is the 2.4G mode, for example, the indicator light 406 lights up blue, and at this time, the indicator light 406 indicates that the 2.4G downlink communication unit 402 in the fusion embedded unit 400 is performing communication, and the 5G module 401 in the fusion embedded unit 400 is in the standby mode; if the indicator light 406 lights up, the fusion embedded unit 400 is indicated to be in a standby mode.

Illustratively, in the fusion embedded unit 400, after the 2.4G downlink communication unit 402 is provided, a 2.4G micro control chip 4021, a low noise amplifier 4022, and one end of a power amplifier 4023,2.4G micro control chip 4021 may be provided in the 2.4G downlink communication unit 402 and one end of the low noise amplifier 4022 is connected, and the other end of the 2.4G micro control chip 4021 is connected to one end of the power amplifier 4023.

The 2.4G micro control chip 4021 controls the module to enter a sleep and wake-up working mode, so as to reduce standby current.

In one example, in the converged embedded unit 400, the 2.4G downstream communication unit 402 used is DL-BK24C, a compact, low cost, long range 2.4G wireless serial module. The high-cost performance 2.4G built-in micro control chip is adopted, the transmitting power is 12dBm, the unobstructed receiving and transmitting distance can reach more than 100 meters, the bidirectional data transparent transmission can be realized, the multi-transmission and 1-transmission or 1-transmission and multi-transmission can be realized, the mutual noninterference is avoided, and the data is processed by the 2.4G micro control chip 4021 of a user. The 2.4G downlink communication unit 402 contains a 2.4G initialization and serial communication program, no user programming is needed, only hardware is needed to be connected, wireless data transmission can be achieved by selecting a required baud rate and frequency channel, the 2.4G downlink communication unit 402 is provided with a (4800/9600/14400/19200) baud rate selection port, the power-on default 9600,2.4G downlink communication unit 402 is provided with 4 frequency (2458/2463/2468/2473) selection ports, the power-on default 2473,2.4G downlink communication unit 402 is provided with a CE sleep control port (default power-on operation), and a client can use the 2.4G micro control chip 4021 to control the 2.4G downlink communication unit 402 to enter a sleep and wake-up working mode, so that standby current is reduced. The 2.4G downlink communication unit 402 adopts a 2.4GHz communication mode, supports GFSK, loRa, FLRC three debug demodulation technologies, and is compatible with bluetooth protocols.

The 2.4G downlink communication unit 402 has the built-in power amplifier 4023 and the low noise amplifier 4022, so that the receiving sensitivity is improved to a certain extent while the maximum transmitting power is increased, and the overall communication stability is enhanced.

In the fusion embedded unit 400, after the 5G module 401 is set, a baseband chip 4011, a power amplifier chip 4012, a radio frequency chip 4013, and a satellite positioning chip 4014 may be set in the 5G module 401, one end of the radio frequency chip 4013 is connected to one end of the baseband chip 4011, and the other end of the radio frequency chip 4013 is connected to one end of the power amplifier chip 4012.

The baseband chip 4011 can be used to control the 5G module 401 to enter a sleep and wake-up mode, so as to reduce standby current.

In one example, for an intelligent fusion terminal of a power system, in order to upgrade a communication capability of the intelligent fusion terminal, a fusion embedded unit 400 is set in the intelligent fusion terminal, and the intelligent fusion terminal communicates with a service end and a base station through the fusion embedded unit 400, where the fusion embedded unit 400 includes a 5G module 401, a 2.4G downlink communication unit 402, an interface unit 403, an antenna unit 404, and a control unit 405.

After the fusion embedded unit 400 is powered on, entering an initialization mode and then entering a waiting mode, when a first interface 4031 in the interface unit 403 receives power service data sent by the fusion terminal, namely first power information, the fusion embedded unit 400 enters a sending processing flow, a control unit 405 obtains the power service data from the first interface 4031 of the interface unit 403 and analyzes the power service data to obtain corresponding communication protocol information, the communication protocol information is identified, if the power service data is determined to be in accordance with a communication protocol corresponding to the 5G module 401, the control unit 405 sends the corresponding power service data to the 5G module 401 for processing, the 5G module 401 sends the received power service data to a base station again, and an indicator 406 indicates that the working state of the fusion embedded unit 400 is in the 5G mode; if it is determined that the power service data conforms to the communication protocol corresponding to the 2.4G downlink communication unit 402, the control unit 405 sends the corresponding power service data to the 2.4G downlink communication unit 402 for processing, and the 2.4G downlink communication unit 402 sends the received power service data to the downlink switch or the sensor again, and during this time, the indicator light 406 indicates that the working state of the fusion embedded unit 400 is the 2.4G mode.

The 5G band antenna of the antenna unit 404 receives the power service data from the base station, the 5G module 401 may obtain the power service data from the 5G band antenna of the antenna unit 404, and send the power service data to the motherboard in the convergence terminal through the second interface 4032 of the interface unit 403, so as to implement 5G remote communication between the convergence terminal and the base station, and during the period, the indicator light 406 indicates that the working state of the convergence embedded unit 400 is in the 5G mode.

The 2.4G band antenna of the antenna unit 404 receives the power service data from the downlink intelligent switch, and the 2.4G downlink communication unit 402 may obtain the power service data from the 2.4G band antenna of the antenna unit 404, and send the power service data to the motherboard in the convergence terminal through the second interface 4032 of the interface unit 403, so as to implement wireless data transmission between the convergence terminal and the downlink intelligent switch, where the indicator light 406 indicates that the working state of the convergence embedded unit 400 is in the 2.4G mode.

In this embodiment, based on the foregoing embodiment, the control unit 405 is specifically configured to: acquiring first electrical information received by the first interface 4031 from a main board in the fusion terminal, and analyzing the first electrical information to obtain protocol information; if the protocol information is determined to represent that the first electric information accords with the communication protocol corresponding to the 5G module 401, the first electric information is sent to the base station through the 5G module 401; if it is determined that the protocol information characterizes that the first electrical information accords with the communication protocol corresponding to the 2.4G downlink communication unit 402, the first electrical information is sent to the downlink switch through the 2.4G downlink communication unit 402; the antenna unit 404 includes a first antenna 4041 and a second antenna 4042,5G module 401 connected to the first antenna 4041, and the 2.4G downlink communication unit 402 is connected to the second antenna 4042; the 5G module 401 is configured to receive the second electricity information through the first antenna 4041, and send the second electricity information to the motherboard in the fusion terminal through the second interface 4032; the 2.4G downlink communication unit 402 is configured to receive the second power consumption information through the second antenna 4042, and send the second power consumption information to the motherboard in the converged terminal through the second interface 4032. A fusion embedded unit 400 is arranged in the fusion terminal and comprises a 5G module 401, a 2.4G downlink communication unit 402, an antenna unit 404 and an interface unit 403, and the fusion embedded unit 400 is determined to enter an information sending flow or an information receiving flow according to a protocol carried by the power service data received by the analysis interface unit 403; or determining whether the fusion embedded unit 400 enters a 5G mode or a 2.4G mode according to the antenna unit 404 receiving the power service data; the fusion terminal does not need to be modified, so that the manufacturing cost is reduced; the fusion terminal has the capability of 5G communication and 2.4G wireless communication, and ensures the normal return of the power service data.

Fig. 5 is a schematic structural diagram of a fusion terminal according to an embodiment of the present application, and as shown in fig. 5, a fusion terminal 500 includes a motherboard 501 and a fusion embedded unit 502 as described above.

Wherein the motherboard 501 is connected 502 with the fusion embedded unit.

For example, for the fusion terminal 500 of the power system, in order to upgrade the communication capability of the fusion terminal 500, a main board 501 and a fusion embedded unit 502 are disposed in the fusion terminal 500, where one end of the main board 501 is connected with one end of the fusion embedded unit 502, based on the fusion embedded unit 502, the main board 501 of the fusion terminal 500 may perform 5G remote communication with a base station, and meanwhile, based on the fusion embedded unit 502, the main board 501 of the fusion terminal 500 may perform 2.4G frequency band micro-power wireless communication with a downlink switch, so that the fusion terminal 500 does not need to be modified, and the fusion terminal 500 has the capability of 5G communication and 2.4G communication, thereby realizing rapid information acquisition.

Fig. 6 is a block diagram of a converged terminal, which may be a computer, a digital broadcasting terminal, a messaging device, etc., shown in accordance with an exemplary embodiment.

The fusion terminal 800 includes a motherboard 801 and a fusion embedded unit 816 as described above.

Wherein motherboard 801 is connected to a fusion embedded unit 816.

The fusion terminal 800 may include one or more of the following components: a processing component 802, a memory 804, a power component 806, a multimedia component 808, an audio component 810, an input/output (I/O) interface 812, and a sensor component 814.

The processing component 802 generally controls overall operation of the fusion terminal 800, such as operations associated with display, data communication, and recording operations. The processing component 802 may include one or more processors 820 to execute instructions to perform all or part of the steps of the methods described above. Further, the processing component 802 can include one or more modules that facilitate interactions between the processing component 802 and other components. For example, the processing component 802 can include a multimedia module to facilitate interaction between the multimedia component 808 and the processing component 802.

The memory 804 is configured to store various types of data to support operations at the fusion terminal 800. Examples of such data include instructions for any application or method operating on the converged terminal 800, contact data, phonebook data, messages, pictures, videos, and the like. The memory 804 may be implemented by any type or combination of volatile or nonvolatile memory devices such as Static Random Access Memory (SRAM), electrically erasable programmable read-only memory (EEPROM), erasable programmable read-only memory (EPROM), programmable read-only memory (PROM), read-only memory (ROM), magnetic memory, flash memory, magnetic or optical disk.

The power supply component 806 provides power to the various components of the fusion terminal 800. The power components 806 may include a power management system, one or more power sources, and other components associated with generating, managing, and distributing power for the fusion terminal 800.

The multimedia component 808 includes a screen between the fusion terminal 800 and the user that provides an output interface. In some embodiments, the screen may include a Liquid Crystal Display (LCD) and a Touch Panel (TP). If the screen includes a touch panel, the screen may be implemented as a touch screen to receive input signals from a user. The touch panel includes one or more touch sensors to sense touches, swipes, and gestures on the touch panel. The touch sensor may sense not only the boundary of a touch or sliding action, but also the duration and pressure associated with the touch or sliding operation. In some embodiments, the multimedia component 808 includes a front camera and/or a rear camera. When the convergence terminal 800 is in an operation mode, such as a photographing mode or a video mode, the front camera and/or the rear camera may receive external multimedia data. Each front camera and rear camera may be a fixed optical lens system or have focal length and optical zoom capabilities.

The audio component 810 is configured to output and/or input audio signals. For example, the audio component 810 includes a Microphone (MIC) configured to receive external audio signals when the convergence terminal 800 is in an operation mode, such as a call mode, a recording mode, and a voice recognition mode. The received audio signal may be further stored in the memory 804 or transmitted via the fusion embedded unit 816. In some embodiments, audio component 810 further includes a speaker for outputting audio signals.

The I/O interface 812 provides an interface between the processing component 802 and peripheral interface modules, which may be a keyboard, click wheel, buttons, etc. These buttons may include, but are not limited to: homepage button, volume button, start button, and lock button.

The sensor assembly 814 includes one or more sensors for providing status assessment of various aspects of the fusion terminal 800. For example, the sensor assembly 814 may detect an on/off state of the fusion terminal 800, a relative positioning of the components, such as a display and keypad of the fusion terminal 800, the sensor assembly 814 may also detect a change in position of the fusion terminal 800 or a component of the fusion terminal 800, the presence or absence of a user's contact with the fusion terminal 800, an orientation or acceleration/deceleration of the fusion terminal 800, and a change in temperature of the fusion terminal 800. The sensor assembly 814 may include a proximity sensor configured to detect the presence of nearby objects without any physical contact. The sensor assembly 814 may also include a light sensor, such as a CMOS or CCD image sensor, for use in imaging applications. In some embodiments, the sensor assembly 814 may also include an acceleration sensor, a gyroscopic sensor, a magnetic sensor, a pressure sensor, or a temperature sensor.

The converged embedded unit 816 is configured to facilitate wired or wireless communication between the converged terminal 800 and other devices. The converged terminal 800 may access a wireless network based on a communication standard, such as WiFi,2G, or 3G, or a combination thereof. In one exemplary embodiment, the fusion embedded unit 816 receives a broadcast signal or broadcast-related information from an external broadcast management system via a broadcast channel. In one exemplary embodiment, the converged embedded unit 816 further includes a Near Field Communication (NFC) module to facilitate short range communications. For example, the NFC module may be implemented based on Radio Frequency Identification (RFID) technology, infrared data association (IrDA) technology, ultra Wideband (UWB) technology, bluetooth (BT) technology, and other technologies.

In an exemplary embodiment, the fusion terminal 800 may be implemented by one or more Application Specific Integrated Circuits (ASICs), digital Signal Processors (DSPs), digital Signal Processing Devices (DSPDs), programmable Logic Devices (PLDs), field Programmable Gate Arrays (FPGAs), controllers, microcontrollers, microprocessors, or other electronic elements for executing the methods described above.

Other embodiments of the present application will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. This application is intended to cover any variations, uses, or adaptations of the application following, in general, the principles of the application and including such departures from the present disclosure as come within known or customary practice within the art to which the application pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the application being indicated by the following claims.

It is to be understood that the present application is not limited to the precise arrangements and instrumentalities shown in the drawings, which have been described above, and that various modifications and changes may be effected without departing from the scope thereof. The scope of the application is limited only by the appended claims.

Claims (11)

1. The fusion embedded unit is characterized by being applied to a fusion terminal and comprises a 5G module, a 2.4G downlink communication unit, an interface unit, an antenna unit and a control unit; the 5G module and the 2.4G downlink communication unit are respectively connected with the antenna unit; the first interface, the 5G module and the 2.4G downlink communication unit in the interface unit are respectively connected with the control unit, and the 5G module and the 2.4G downlink communication unit are respectively connected with the second interface in the interface unit;

the control unit is used for acquiring first electric information received by the first interface from a main board in the fusion terminal, and sending the first electric information out through the 5G module or the 2.4G downlink communication unit; the first power information characterizes power business data sent by the power fusion terminal;

The 5G module is used for receiving second electricity utilization information through the antenna unit and sending the second electricity utilization information to a main board in the fusion terminal through the second interface; the second power consumption information represents power service data sent by the power service terminal;

the 2.4G downlink communication unit is configured to receive the second power consumption information through the antenna unit, and send the second power consumption information to a motherboard in the fusion terminal through the second interface.

2. The fusion embedded unit according to claim 1, wherein the control unit is specifically configured to:

acquiring first electric information received by the first interface from a main board in the fusion terminal, and analyzing the first electric information to obtain protocol information;

if the protocol information is determined to characterize that the first electric information accords with the communication protocol corresponding to the 5G module, the first electric information is sent to a base station through the 5G module;

and if the protocol information is determined to characterize that the first electrical information accords with the communication protocol corresponding to the 2.4G downlink communication unit, transmitting the first electrical information to a downlink switch through the 2.4G downlink communication unit.

3. The fusion embedded unit of claim 2, wherein the control unit is further configured to:

and if the protocol information characterizes that the first electrical information does not accord with the communication protocol corresponding to the 5G module and does not accord with the communication protocol corresponding to the 2.4G downlink communication unit, determining that the first electrical information is not transmitted.

4. The fusion embedded unit of claim 1, wherein the antenna unit comprises a first antenna and a second antenna, the 5G module is connected to the first antenna, and the 2.4G downlink communication unit is connected to the second antenna;

the 5G module is used for receiving second electricity utilization information through the first antenna and sending the second electricity utilization information to a main board in the fusion terminal through the second interface;

the 2.4G downlink communication unit is configured to receive the second power consumption information through the second antenna, and send the second power consumption information to a motherboard in the converged terminal through the second interface.

5. The fused embedded unit of claim 4, wherein the first antenna is a 5G band antenna and the second antenna is a 2.4G band antenna.

6. The fusion embedded unit of claim 4, wherein the antenna unit further comprises: a satellite antenna.

7. The fusion embedded unit of claim 1, wherein the fusion embedded unit is configured to enter a waiting mode after entering an initialization procedure; wherein the wait mode characterizes the converged embedded unit to initiate an internal sleep function.

8. The fusion embedded unit of claim 1, further comprising an indicator light and a power source; the 5G module, the 2.4G downlink communication unit and the interface unit are respectively connected with the indicator lamp;

the power supply is used for providing electric energy for the fusion embedded unit;

and the indicator lamp is used for indicating the working state of the fusion embedded unit.

9. The fusion embedded unit of any one of claims 1-8, wherein the 2.4G downstream communication unit comprises a 2.4G micro control chip, a low noise amplifier, and a power amplifier; the low-noise amplifier and the power amplifier are respectively connected with the 2.4G micro-control chip;

The 2.4G micro-control chip is used for controlling the 2.4G downlink communication unit to enter a working mode or a dormant mode.

10. The fusion embedded unit of any one of claims 1-8, wherein the 5G module comprises a baseband chip, a power amplifier chip, a radio frequency chip, and a satellite positioning chip; the baseband chip and the power amplifier chip are respectively connected with the radio frequency chip;

the baseband chip is used for controlling the 5G module to enter a working mode or a dormant mode.

11. A fusion terminal, comprising a main board and the fusion embedded unit according to any one of claims 1-10;

the main board is connected with the fusion embedded unit.

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