CN108880602B - Multi-way selector switch and related products - Google Patents

Abstract

The embodiment of the application discloses a multi-path selection switch and a related product, wherein wireless communication equipment comprises an antenna system and a radio frequency circuit, the wireless communication equipment supports a double-frequency double-transmission path mode, and the antenna system comprises 4 antennas; the multi-way selector switch comprises 6T ports and 4P ports, wherein the 6T ports comprise 2 first T ports and 4 second T ports; each first T port is fully connected with 4P ports, each second T port is connected with 3P ports in the 4P ports, the multi-way selection switch is used for being connected with a radio frequency circuit and an antenna system so as to realize a first function and a second function of the wireless communication equipment in a frequency division multiplexing FDD mode, the first function is a function of supporting alternate sending and sending of 4-port SRS between the transmitting antennas through the sounding reference signal SRS, and the second function is a function of supporting the 4 antennas to receive data simultaneously. The embodiment of the application can improve the radio frequency index performance and functionality of the electronic equipment.

Description

Multi-way selector switch and related products

Technical Field

The application relates to the technical field of mobile terminals, in particular to a multi-way selection switch and a related product.

Background

With the widespread use of a large number of electronic devices such as smart phones, smart phones have more and more applications and more powerful functions, and smart phones are developed towards diversification and personalization directions and become indispensable electronic products in user life. Electronic devices in the fourth Generation (4 th Generation, 4G) mobile communication system generally adopt a single-antenna or dual-antenna Radio frequency system architecture, and electronic devices supporting the 4-antenna Radio frequency system architecture are proposed in the New air interface (New Radio, NR) system of the fifth Generation (5 th Generation, 5G) mobile communication system.

Disclosure of Invention

The embodiment of the application provides a multi-way selection switch and a related product, so as to improve the radio frequency index performance and functionality of electronic equipment.

In a first aspect, embodiments of the present application provide a multi-way selector switch, which is applied to a wireless communication device,

the wireless communication equipment comprises an antenna system and a radio frequency circuit, the wireless communication equipment supports a dual-frequency dual-transmission mode, and the antenna system comprises 4 antennas;

the multi-way selector switch comprises 6T ports and 4P ports, wherein the 6T ports comprise 2 first T ports and 4 second T ports; each first T port is fully connected with the 4P ports, each second T port is connected with 3P ports in the 4P ports, the P ports connected with the plurality of second T ports supporting the signal receiving function of the same frequency band cover the 4P ports, and the P ports connected with each T port in the 4T ports in the signal receiving state are different from each other;

the multi-path selection switch is used for connecting the radio frequency circuit and the antenna system to realize the preset function of the wireless communication equipment in a frequency division multiplexing FDD mode, the preset function comprises a first function and a second function, the first function is used for supporting alternate sending of SRS between the transmitting antennas and sending of the SRS with 4 ports, and the second function is used for supporting the function of simultaneously receiving data by the 4 antennas.

In a second aspect, an embodiment of the present application provides a function control method, which is applied to a wireless communication device, where the wireless communication device includes an antenna system, a radio frequency circuit, and a multi-way selection switch, the wireless communication device supports a dual-frequency dual-transmission mode, the multi-way selection switch includes 6T ports and 4P ports, the 6T ports include 2 first T ports and 4 second T ports, each first T port is fully connected to the 4P ports, each second T port is connected to 3P ports of the 4P ports, the P ports connected to a plurality of second T ports supporting signal reception functions in the same frequency band cover the 4P ports, and the P ports connected to each T port of the 4T ports in a signal reception state are different from each other; the method comprises the following steps:

the wireless communication equipment determines to execute a preset function, wherein the preset function comprises a first function and a second function, the first function is a function of supporting alternate transmission of a Sounding Reference Signal (SRS) among transmitting antennas and transmitting a 4-port SRS, and the second function is a function of supporting the 4 antennas to simultaneously receive data;

and in the process of starting the first function, the wireless communication equipment adjusts the matching states between the 3T ports and the 4P ports currently occupied by the second function according to the P port currently occupied by the first function.

In a third aspect, an embodiment of the present application provides a radio frequency system, including an antenna system, a radio frequency circuit, and the multi-way selection switch according to any one of the first aspect;

the multi-path selection switch is used for connecting the radio frequency circuit and the antenna system to realize the preset function of the wireless communication equipment in a frequency division multiplexing FDD mode, the preset function comprises a first function and a second function, the first function is used for supporting alternate sending of SRS between the transmitting antennas and sending of the SRS with 4 ports, and the second function is used for supporting the function of simultaneously receiving data by the 4 antennas.

In a fourth aspect, an embodiment of the present application provides a wireless communication device, including an antenna system, a radio frequency circuit, and the multi-way selection switch according to any one of the first aspect;

the multi-path selection switch is used for connecting the radio frequency circuit and the antenna system to realize the preset function of the wireless communication equipment in a frequency division multiplexing FDD mode, the preset function comprises a first function and a second function, the first function is a function of supporting alternate sending of SRS between transmitting antennas and sending of 4-port SRS, and the second function is a function of supporting simultaneous data receiving of the 4 antennas;

the wireless communication device includes at least any one of: electronic equipment, base station.

It can be seen that, in the embodiment of the present application, a wireless communication device includes an antenna system, a radio frequency circuit, and a multi-way selector switch, where the wireless communication device supports a dual-frequency dual-transmission mode, the antenna system specifically includes 4 antennas, the multi-way selector switch includes 6T ports and 4P ports, and the 6T ports include 2 first T ports and 4 second T ports; each first T port is connected with 4P ports, each second T port is connected with 4P ports of the 4P ports, the second T port of the multi-path selection switch can realize the preset function in an FDD mode only by being connected with 3P ports, and compared with the switch with all T ports connected completely, the switch number can be effectively reduced, so that the insertion loss of a radio frequency link switch is reduced, the radio frequency index performance of electronic equipment is improved, and compared with the case that the second T port is connected with only a single P port, the preset function in the FDD mode can be supported, namely the functionality of the electronic equipment is expanded.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a multi-way selector switch disclosed in an embodiment of the present application;

fig. 2 is a schematic structural diagram of a 4P6T switch disclosed in the embodiments of the present application;

fig. 3A is a schematic structural diagram of 4P6T with all T ports fully connected according to the embodiment of the present application;

FIG. 3B is a schematic diagram of a simplified connected 4P6T according to an embodiment of the present disclosure;

fig. 4 is a schematic structural diagram of a radio frequency circuit disclosed in an embodiment of the present application;

fig. 5 is a schematic structural diagram of a first transceiving signal processing circuit disclosed in an embodiment of the present application;

fig. 6 is a schematic structural diagram of a received signal processing circuit according to an embodiment of the present application;

fig. 7 is a schematic structural diagram of an rf circuit integrated in a separate circuit module according to an embodiment of the present application;

fig. 8 is a schematic structural diagram of another rf circuit integrated in a separate circuit module according to an embodiment of the present application;

fig. 9 is a schematic structural diagram of another rf circuit integrated in a separate circuit module according to an embodiment of the present application;

fig. 10 is a schematic structural diagram of another rf circuit integrated in a separate circuit module according to an embodiment of the present application;

fig. 11 is a schematic structural diagram of another rf circuit integrated in a separate circuit module according to an embodiment of the present application;

fig. 12 is an exemplary structure of an antenna system of an electronic device disclosed in an embodiment of the present application;

fig. 13 is an exemplary structure of another antenna system of an electronic device disclosed in an embodiment of the present application;

FIG. 14 is a flow chart illustrating a method for controlling functions disclosed in an embodiment of the present application;

fig. 15 is an exemplary architecture of a radio frequency system disclosed in an embodiment of the present application;

fig. 16 is an exemplary structure of an electronic device disclosed in an embodiment of the present application;

fig. 17 is a schematic diagram of a wireless charging receiver multiplexing an antenna of a wireless communication device according to an embodiment of the present disclosure;

fig. 18 is a schematic structural diagram of a loop array antenna composed of 4 antennas according to an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without inventive step, are within the scope of the present disclosure.

The terms "first," "second," and the like in the description and claims of the present application and in the above-described drawings are used for distinguishing between different objects and not for describing a particular order. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements but may alternatively include other steps or elements not expressly listed or inherent to such process, system, article, or apparatus.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

The wireless communication device according to the embodiment of the present application may include an electronic device or a network device, and the electronic device may include various handheld devices, vehicle-mounted devices, wearable devices, computing devices or other processing devices connected to a wireless modem, and various forms of User Equipment (UE) (e.g., a Mobile phone), a Mobile Station (MS), a terminal device (terminal device), and the like. For convenience of description, the above-mentioned devices are collectively referred to as electronic devices. The network devices may include base stations, access points, and the like.

In the following embodiments, the wireless communication device is described by taking an electronic device as an example.

At present, the Sounding Reference Signal (SRS) switching (switching)4 antenna transmission function of a Mobile phone is a necessary option of a China Mobile communication Group (China Mobile Communications Group co, Ltd, CMCC) in "white paper terminal of chinese Mobile 5G scale test technology", and is selectable in a third Generation Partnership Project (3rd Generation Partnership Project, 3GPP), and the SRS is mainly used for a base station to perform beam forming of a downlink large-scale (Massive) Multiple-Input Multiple-Output (MIMO) antenna array by measuring uplink signals of the Mobile phone 4 antenna so as to confirm 4-channel quality and parameters, and then perform downlink large-scale (Massive-Input Multiple-Output (MIMO) antenna array for the 4-channel according to channel reciprocity, so that the downlink 4x4MIMO obtains the best data transmission performance. Where 4x4MIMO means that the base station has 4 antennas to transmit data and the terminal device has 4 antennas to receive data.

In order to meet the requirement of switching transmission of a 4-antenna SRS and simultaneous operation of a downlink 4X4MIMO function in an FDD NR system and/or an FDD LTE system, the radio frequency architecture provided in the embodiment of the present application, which uses a simplified 4P6T antenna switch as a core, can reduce the number of switches connected in series in each path (by integrating all or part of the switches into a 4P6T switch) compared with a 3P 3T/DPDT/multi-path small-switch switching scheme, thereby reducing link loss and optimizing the overall transmission and reception performance of the terminal. The following describes embodiments of the present application in detail.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a multi-way selector switch disclosed in an embodiment of the present application, where the multi-way selector switch 10 is applied to an electronic device 100, the electronic device 100 includes an antenna system 20 and a radio frequency circuit 30, the electronic device 100 supports a dual-frequency dual transmission mode, the antenna system 20 includes 4 antennas, the multi-way selector switch 10 includes 6T ports and 4P ports, and the 6T ports include 2 first T ports and 4 second T ports; each first T port is fully connected with 4P ports, each second T port is connected with 3P ports in the 4P ports, the P ports connected with the plurality of second T ports supporting the signal receiving function of the same frequency band cover the 4P ports, and the P ports connected with each T port in the 4T ports in the signal receiving state are different;

the multi-way selector switch 10 is configured to connect the radio frequency circuit 30 and the antenna system 20 to implement a preset function of the electronic device 100 in the frequency division multiplexing FDD system, where the preset function includes a first function and a second function, the first function is to support alternate transmission and transmission of the SRS at 4 ports between the transmitting antennas through the SRS, and the second function is to support simultaneous data reception of 4 antennas.

The transmitting antenna refers to an antenna supporting a transmitting function among the 4 antennas. The 4 antennas in the embodiment of the present application can support the transmission function.

The electronic device may specifically be a 5G NR Mobile phone terminal or other 5G NR terminal devices, such as Customer Premise Equipment (CPE) or a portable broadband wireless device (MIFI).

In the embodiment of the present application, the P Port is called a Port (polarization) Port in english, the P Port is called a Port connected to an antenna, the T Port is called a thru, and the T Port is called a Port connected to a radio frequency circuit in english. In the embodiment of the present application, there are 4P ports and 6T ports, and in order to facilitate an intuitive understanding of the structure of the multi-way switch 10, the multi-way switch 10 in the embodiment of the present application may also be referred to as a "4P 6T switch".

In the embodiment of the present application, the full connection is defined for the T port, which means that the T port is connected to all the P ports respectively. The first T port is a full connection port, and the first T port is connected to all the 4P ports.

It should be noted that, in the embodiments of the present application, the connection between the T port and the P port refers to that the T port and the P port can establish a connection path, but the connection path is not necessarily conductive. For example, the first T port is connected to all of the 4P ports, which means that the first T port can communicate with the 4P ports. Specifically, at the same time, the multi-way selector switch 10 can only selectively control the first T port to communicate with 1 of the 4P ports, and the first T port can receive and transmit signals with the communicating P ports; at this time, although the first T port is connected to the other 3P ports, no connection path is established, that is, no connection is made, and the first T port cannot transmit and receive signals to and from the other 3P ports.

The function of supporting alternate transmission of the SRS through the sounding reference signal between the transmitting antennas, and transmitting the SRS at 4 ports refers to a process in which the electronic device 100 interacts with the base station through a polling mechanism to determine the uplink channel quality corresponding to each of the 4 antennas. When the electronic device is in a downlink 4x4MIMO working mode, the T ports and the P ports in 4 downlink channels of the same frequency band are in one-to-one correspondence. In design principle, four T ports supporting the receiving function in the same frequency band must be connected to 4P ports, respectively, so as to ensure that the downlink four-path receiving function can be realized.

In the multi-path selection switch provided by the embodiment of the application, only 1 first T port in 6T ports is fully connected with the 4P ports, and each port in the second T port is only connected with 3 antennas for receiving, so that the number, volume and cost of field effect transistors built in the 4P6T switch can be reduced compared with a mode that each T port in the 4T ports is fully connected with the 4P ports, and synchronous operation of the SRS function and the downlink 4X4MIMO function in an FDD mode is expanded in function compared with a simplest state that each port in the second T port is only connected with a single P port, so that the applicability is improved.

Optionally, the 4 second T ports are T ports for receiving a first frequency band or a second frequency band, and the first frequency band and the second frequency band are not overlapped; the 4P ports are connected with the 4 antennas in a one-to-one correspondence manner; the 2 first T ports are T ports for first band reception and second band reception.

The first frequency band and the second frequency band are both 5G NR frequency bands. For convenience of explanation, a first frequency Band supported by the 5G NR electronic device is represented by an "NR Band Nx" or Nx frequency Band, and a second frequency Band supported by the 5G NR electronic device is represented by an "NR Band Ny" or Ny frequency Band. For example, the first frequency band ranges from 3.3GHz to 3.8GHz, and the second frequency band ranges from 4.4GHz to 5 GHz; or the first frequency band range is 4.4GHz-5GHz, and the second frequency band range is 3.3GHz-3.8 GHz.

In the embodiment of the present application, the 6T ports are divided into two types, the first type is a first T port, the number of the first T ports is 2, the first T port is a full-connection port, and the first T port is a port for transmission and reception of a first frequency Band (NR Band Nx) and a second frequency Band (NR Band Ny); the second type is a second T port, which is a port for NR Band Nx reception or NR Band Ny reception, and the number of the second T port is 4. Referring to fig. 2, fig. 2 is a schematic structural diagram of a 4P6T switch disclosed in the embodiments of the present application. As shown in fig. 2, the 2 first T ports are respectively an "NR Band Nx + Ny TRX 1" port and an "NR Band Ny + Ny TRX 2" port; the 4 second T ports are respectively an "NR Band Nx RX 3" port, an "NR Band Ny RX 3" port, an "NR Band Nx RX 4" port, and an "NR Band Ny RX 4" port. The 4P ports are P1 port, P2 port, P3 port and P4 port, respectively. Wherein, the "NR Band Nx + Ny TRX 1" port is connected with the P1 port, the P2 port, the P3 port and the P4 port. The "NR Band Ny + Ny TRX 2" port is connected to all of the P1 port, the P2 port, the P3 port, and the P4 port. The "NR Band Nx RX 3" port and the "NR Band Nx RX 4" port are both ports for NR Band Nx reception, and the "NR Band Ny RX 3" port and the "NR Band Ny RX 4" port are both ports for NR Band Ny reception. The number of P ports to which the "NR Band Nx RX 3" port, the "NR Band Ny RX 3" port, the "NR Band Nx RX 4" port, and the "NR Band Ny RX 4" port are connected is 3, and the P ports to which the 4 second T ports are connected cover the 4P ports, the "NR Band Nx RX 3" port in fig. 2 is connected to the P1 port, the P2 port, and the P3 port, the "NR Band Ny RX 3" port is connected to the P2 port, the P3 port, and the P4 port, the "NR Band Nx RX 4" port is connected to the P1 port, the P3 port, and the P4 port, and the "NR Band Ny RX 4" port is connected to the P1 port, the P2 port, and the P4 port. It should be noted that the connection manner between the second T port and the P port in fig. 2 is only one possible example, and the condition that "the P port connected to the 4 second T ports covers 4P ports" is satisfied.

The P port to which the 4 second T ports are connected covers the 4P ports means that: all the P ports to which the 4 second T ports are connected include 4P ports of P1 port, P2 port, P3 port, P4 port.

The multi-way change-over switch 10 comprises 60 first switch tubes, 6 second switch tubes and 4 third switch tubes, the second switch tubes correspond to T ports, the third switch tubes correspond to P ports, every 3 first switch tubes are connected in series to form a switch subunit between the T ports and the P ports, 2 first switch tubes at two ends of the switch subunit are respectively connected with 1T port and 1P port, the first switch tube in the middle of the switch subunit is grounded, and gate poles of each first switch tube, each second switch tube and each third switch tube are connected with a switch control chip.

The first switch tube, the second switch tube and the third switch tube can be composed of field effect tubes.

In the multi-way selector switch 10 described in this embodiment of the present application, the connection between the T port and the P port refers to a state in which the T port is connected to the P port through a first switch tube, the first switch tube is used to control conduction between the T port and the P port (specifically, including unidirectional conduction from the T port to the P port and unidirectional conduction from the P port to the T port), the switch subunit may be, for example, a switch array composed of 3 first switch tubes (for example, MOS transistors) (when the switch subunit is turned off, if there is no ground, parasitic parameters (for example, parasitic capacitance, parasitic inductance, and the like) have too great influence on performance of other conducting ports, so that the switch subunit is set to be 3 MOS tubes, when the switch subunit is turned off, 2 MOS tubes on both sides are turned off, and the MOS tube in the middle is turned on. In addition to the first switch tube used between the T port and the P port, the multiplexer 10 further includes a second switch tube on the T port side and a third switch tube on the P port side, where the second switch tube and the third switch tube may also be referred to as ground switch tubes, one ground switch tube may be configured for each T port, one ground switch tube may be configured for each P port, and when the T port or the P port does not perform signal transmission or reception, the ground switch tubes configured for the T port or the P port are turned on, and when the T port or the P port performs signal reception or signal transmission, the ground switch tubes configured for the T port or the P port are turned off. The second switch tube is used to enable a corresponding port (T port or P port), for example, the second switch tube and the third switch tube may be 1 MOS tube, and the specific forms of the first switch tube, the second switch tube and the third switch tube are not limited herein. In a specific implementation, the electronic device 100 may control the conduction of the path between the T port and the P port through the first switch tube, and specifically, the electronic device 100 may be provided with a dedicated controller connected to the switch tube in the multi-way switch 10.

The electronic device 100 may connect the gate of each MOS transistor in the first, second, and third switching transistors through a port of the switch control chip, the switch control chip may employ an MIPI interface, and the electronic device 100 controls a signal of a driving port of the switch control chip to control a connection state between any T port and any P port.

Therefore, in this example, the switch subunit of the multi-way selector switch includes three second switch tubes, and the middle second switch tube is grounded, so that the influence of the parasitic parameters of the current switch tube on the performance of other conducting ports can be avoided in the open circuit state, and the switch control stability is improved.

Because only 2T ports of the 6T ports are fully connected with the 4P ports, and other T ports only need to be connected with 3P ports, the preset function in an FDD mode can be realized, compared with all T port fully connected switches, the number, volume and cost of field effect transistors built in the 4P6T switch can be reduced, and the performance is improved. This section is explained in detail below.

The multiplexer 10 is formed by a field effect transistor. For example, if each of the 6T ports is fully connected to 4P ports, the number of fets in the mux switch is 6+6 × 4 × 3+4 — 82 as the exemplary structure diagram of the mux switch shown in fig. 3A. In this embodiment, only 2T ports of the 6T ports are all connected to 4P ports, and the other 4T ports are respectively connected to 3P ports of the 4P ports, so as to obtain an exemplary structure diagram of the multi-way selector switch shown in fig. 3B, where the number of field-effect transistors of the multi-way selector switch is 6+ (3 × 4+ (6-2) × 3+4 ═ 70. Obviously, by adopting the embodiment of the application, the number, the volume and the cost of the field effect transistors built in the 4P6T switch can be reduced, and the performance is improved.

Optionally, please refer to fig. 4, where fig. 4 is a schematic structural diagram of a radio frequency circuit disclosed in an embodiment of the present application. As shown in fig. 4, the rf circuit 30 includes an rf transceiver 31, 2 transceiver signal processing circuits, and 4 receive signal processing circuits. The 2 transceiver signal processing circuits are a first transceiver signal processing circuit 321 and a second transceiver signal processing circuit 322; the 4 reception signal processing circuits are a first reception signal processing circuit 331, a second reception signal processing circuit 332, a third reception signal processing circuit 333, and a fourth reception signal processing circuit 334, respectively. The first transceiving signal processing circuit 321 is formed by coupling a transmitting path supporting transmission of the first frequency Band (NR Band Nx), a receiving path supporting reception of the first frequency Band (NR Band Nx), a transmitting path supporting transmission of the second frequency Band (NR Band Ny), and a receiving path supporting reception of the second frequency Band (NR Band Ny), and please refer to the description of the first transceiving signal processing circuit in fig. 5. The 4 received signal processing circuits include 2 received signal processing circuits supporting reception in the first frequency Band (NR Band Nx) and 2 received signal processing circuits supporting reception in the second frequency Band (NR Band Ny), and refer to fig. 6 for a description of the first received signal processing circuit.

As shown in fig. 4, the 4 received signal processing circuits are respectively: a first received signal processing circuit 331, a second received signal processing circuit 332, a third received signal processing circuit 333, and a fourth received signal processing circuit 334. Among them, the first received signal processing circuit 331 and the third received signal processing circuit 333 are both received signal processing circuits that support signal processing of NR Band Nx; the second received signal processing circuit 332 and the fourth received signal processing circuit 334 are each a received signal processing circuit that supports signal processing of NR Band Ny.

In the embodiment of the present application, the radio frequency transceiver 31 is used for transmitting and receiving radio frequency signals. In the uplink, the radio frequency transceiver 31 is configured to modulate the baseband signal into a transmission radio frequency signal, and the transmission radio frequency signal is amplified, filtered, and the like by the first transceiving signal processing circuit 321 or the second transceiving signal processing circuit 322, and then converted into an electromagnetic wave of a specific frequency band by an antenna to be transmitted; in the downlink, the antenna receives an electromagnetic wave signal in a specific frequency band, converts the electromagnetic wave signal into a radio frequency signal, performs filtering amplification and other processing on the radio frequency signal, and sends the radio frequency signal to the radio frequency transceiver 31, and the radio frequency transceiver 31 is configured to demodulate the received radio frequency signal and convert the radio frequency signal into a baseband signal for processing by a baseband chip.

In the embodiment of the present application, the first transceiving signal processing circuit 321 is formed by coupling a transmission path supporting transmission of a first frequency Band (NR Band Nx), a reception path supporting reception of the first frequency Band (NR Band Nx), a transmission path supporting transmission of a second frequency Band (NR Band Ny), and a reception path supporting reception of the second frequency Band (NR Band Ny). The first transceiving signal processing circuit 321 and the second transceiving signal processing circuit 322 each include 2 receiving ports, 2 transmitting ports, and 1 transceiving port. Each receive signal processing circuit includes 1 receive port and 1 transmit port.

The multi-way selector switch 10 includes 2 first T ports and 4 second T ports, and as shown in fig. 4, the 2 first T ports (T1 port and T2 port) are connected to the transceiving port of the first transceiving signal processing circuit 321 and the transceiving port of the second transceiving signal processing circuit 322, respectively, and the 4 second T ports (T3 port, T4 port, T5 port, and T6 port) are connected to the transceiving port of the first receiving signal processing circuit 331, the transceiving port of the second receiving signal processing circuit 332, the transceiving port of the third receiving signal processing circuit 333, and the receiving port of the fourth receiving signal processing circuit 334, respectively.

Since the radio frequency transceiver 31 needs to be adapted to the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322, the first receiving signal processing circuit 331, the second receiving signal processing circuit 332, the third receiving signal processing circuit 333, and the fourth receiving signal processing circuit 334, the radio frequency transceiver 31 includes at least 4 transmitting ports and 8 receiving ports. As shown in fig. 4, the radio frequency transceiver 31 includes 4 transmission ports: "TX 1_ Nx" port, "TX 1_ Ny" port, "TX 2_ Nx" port, and "TX 2_ Ny" port. 8 receiving ports: "RX 1_ Nx" port, "RX 1_ Ny" port, "RX 2_ Nx" port, "RX 2_ Ny" port, "RX 3_ Nx" port, "RX 3_ Ny" port, "RX 4_ Nx" port, "RX 4_ Ny" port. Wherein the "TX 1_ Nx" port is connected to the first receiving port of the first transceiving signal processing circuit 321, the "TX 1_ Ny" port is connected to the second receiving port of the first transceiving signal processing circuit 321, the "TX 2_ Nx" port is connected to the first receiving port of the second transceiving signal processing circuit 322, the "TX 2_ Ny" port is connected to the second receiving port of the second transceiving signal processing circuit 322, the "RX 1_ Nx" port is connected to the first transmitting port of the first transceiving signal processing circuit 321, the "RX 1_ Ny" port is connected to the second transmitting port of the first transceiving signal processing circuit 321, the "RX 2_ Nx" port is connected to the first transmitting port of the second transceiving signal processing circuit 322, the "RX 2_ Ny" port is connected to the second transmitting port of the second transceiving signal processing circuit 322, the "RX 3_ Nx" port is connected to the transmitting port of the first receiving signal processing circuit 331, the "RX 3_ Ny" port is connected to the transmitting port of the second receiving signal processing circuit 332, the "RX 4_ Nx" port is connected to the transmission port of the third reception signal processing circuit 333, and the "RX 4_ Ny" port is connected to the transmission port of the fourth reception signal processing circuit 334.

Please refer to fig. 5, wherein fig. 5 is a schematic structural diagram of a first transceiver circuit according to an embodiment of the present disclosure. As shown in fig. 5, the first transceiving signal processing circuit 321 includes a first power amplifier 3211 supporting a first frequency Band (NR Band Nx), a second power amplifier 3212 supporting a second frequency Band (NR Band Ny), a first low noise amplifier 3213 supporting the first frequency Band (NR Band Nx), a second low noise amplifier 3214 supporting the second frequency Band (NR Band Ny), a first duplexer 3215, a second duplexer 3216, a first coupler 3217, and a first selection switch 3218, an input port of the first power amplifier 3211 and an input port of the second power amplifier 3212 are respectively connected to corresponding transmitting ports of the radio frequency transceiver 31, an output port of the first low noise amplifier 3212 and an output port of the second low noise amplifier 3214 are respectively connected to corresponding receiving ports of the radio frequency transceiver 31, an output port of the first power amplifier 3211 is connected to a signal receiving port of the first duplexer 3215, an input port of the first low noise amplifier 3213 is connected to a signal transmitting port of a first duplexer 3215, and a transceiving common port of the first duplexer 3215 is connected to a first port of a first coupler 3217; an output port of the second power amplifier 3212 is connected to a signal receiving port of the second duplexer 3218, an input port of the second low noise amplifier 3214 is connected to a signal transmitting port of the second duplexer 3218, and a common transceiving port of the second duplexer 3218 is connected to a second port of the first coupler 3217; a third port of the first coupler 3217 is connected to a first fixed port of a first selector switch 3218, a fourth port of the first coupler 3217 is connected to a second fixed port of the first selector switch 3218, and a selection port of the first selector switch 3215 is connected to one of the first T ports. The first Power Amplifier (PA) 3211 and the second Power amplifier 3212 are rf Power amplifiers for amplifying rf signals transmitted by the rf transceiver 31. The first power amplifier 3211 may amplify a radio frequency signal in a first frequency band, and the second power amplifier 3212 may amplify a radio frequency signal in a second frequency band.

A first Low Noise Amplifier (LNA) 3213 and a second LNA 3214 are used to amplify the radio frequency signal. The signal-to-noise ratio of the output radio frequency signal can be improved by adopting the low noise amplifier.

The first duplexer 3215 may isolate the rf signal transmitted by the first power amplifier 3211 from the signal received by the first low noise amplifier 3213, so as to prevent the rf signal transmitted by the first power amplifier 3211 from being retransmitted to the rf transceiver 31. The second duplexer 3216 may isolate the rf signal transmitted by the second power amplifier 3212 from the signal received by the second low noise amplifier 3214, so as to prevent the rf signal transmitted by the second power amplifier 3212 from being retransmitted to the rf transceiver 31.

The first coupler 3217 may mix the two rf signals and output the mixed signal. Optionally, the first coupler 3217 may also have a power distribution function, which is used to divide the power of the input signal into several paths and feed the several paths back to the corresponding receiving ports of the rf transceiver 31, so that the rf transceiver 31 can adjust the power of the rf signal transmitted by the rf transceiver 31.

The first selection switch 3218 may be a single-pole double-throw switch, when a selection port of the first selection switch 3218 is connected to a first fixed port of the first selection switch 3218, the first power amplifier 3211, the first low noise amplifier 3213, and the first duplexer 3215 of the first transceiving signal processing circuit 321 form a transceiving path, and at this time, the first transceiving signal processing circuit 321 is configured to process a signal in a first frequency Band (NR Band Nx). When the selection port of the first selection switch 3218 is connected to the second fixed port of the first selection switch 3218, the second power amplifier 3212, the second low noise amplifier 3214, and the second duplexer 3216 of the first transceiving signal processing circuit 321 form a transceiving path, and at this time, the first transceiving signal processing circuit 321 is configured to process a signal in the second frequency Band (NR Band Ny). The second transceiving processing circuit 322 in fig. 4 has a similar structure to the first transceiving processing circuit 321, and is not described herein again.

The specific structure of the transceiver processing circuit in fig. 5 is only one possible example, and components may be reduced or increased according to actual needs.

Please refer to fig. 6 for a specific structure of the received signal processing circuit, and fig. 6 is a schematic structural diagram of a received signal processing circuit according to an embodiment of the present disclosure. As shown in fig. 6, the first received signal processing circuit 331 includes a low noise amplifier 3311 supporting a first frequency Band (NR Band Nx), a filter 3312 supporting the passage of the first frequency Band (NR Band Nx), an output port of the low noise amplifier 3311 being connected to a corresponding receiving port for reception of the first frequency Band in the radio frequency transceiver 31, an input port of the low noise amplifier 3311 being connected to an output port of the filter 3312, and an input port of the filter 3312 being connected to a T port for reception of the first frequency Band among the 4 second T ports. The first received signal processing circuit 331 is a received signal processing circuit supporting reception in the first frequency band.

The second received signal processing circuit 332 includes a low noise amplifier 3321 supporting the second frequency Band (NR Band Ny), a filter 3322 supporting the passage of the second frequency Band (NR Band Ny); an output port of the low noise amplifier 3321 is connected to a corresponding receiving port for receiving in the second frequency band in the radio frequency transceiver 31, an input port of the low noise amplifier 3321 is connected to an output port of the filter 3322, and an input port of the filter 3322 is connected to a T port for receiving in the second frequency band among the 4 second T ports. The second received signal processing circuit 332 is a received signal processing circuit supporting reception in the second frequency band.

In this embodiment, the filter (filter)3312 and the filter 3322 may be band-pass filters, wherein the filter 3312 may filter the rf signal received at the second T port, and the filter 3312 only allows the rf signal in the first frequency band to pass through. The filter 3322 may filter the rf signals received at the second T port, and the filter 3322 only allows the rf signals in the second frequency band to pass through.

A Low Noise Amplifier (LNA) 3311 is used to amplify the radio frequency signal passing through the filter 3312, and the low noise amplifier 3312 is used to amplify the radio frequency signal passing through the filter 3322. The signal-to-noise ratio of the output radio frequency signal can be improved by adopting the low noise amplifier.

The first received signal processing circuit 331 and the third received signal processing circuit 333 in fig. 4 may be the same received signal processing circuit, and both are received signal processing circuits supporting reception in the first frequency band.

The second received signal processing circuit 332 and the fourth received signal processing circuit 334 in fig. 4 may be the same received signal processing circuit, and both are received signal processing circuits supporting reception in the second frequency band.

In order to increase the integration degree of the radio frequency circuit, the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322, and the 4 receiving signal processing circuits (the first receiving signal processing circuit 331, the second receiving signal processing circuit 332, the third receiving signal processing circuit 333, and the fourth receiving signal processing circuit 334) in the radio frequency circuit 30 in fig. 4 may be integrated in 1 independent circuit module. Please refer to fig. 7. Fig. 7 is a schematic structural diagram of a radio frequency circuit integrated in a separate circuit module according to an embodiment of the present application. As shown in fig. 7, the first transmission/reception signal processing circuit 321, the second transmission/reception signal processing circuit 322, the first reception signal processing circuit 331, the second reception signal processing circuit 332, the third reception signal processing circuit 333, and the fourth reception signal processing circuit 334 are integrated in 1 independent circuit module 41. The independent circuit module 41 includes 12 ports (such as 420, 421, 422, 423, 424, 425, 426, 427, 428, 429, 430, 431 shown in fig. 7) connected to the radio frequency transceiver 31, and 6 ports (such as 411, 412, 413, 414, 415, 416 shown in fig. 7) connected to the multiplexer switch 10. 421, 423, 425, and 427 are receiving ports of the independent circuit module 41, 420, 422, 423, 424, 426, 428, 429, 430, and 431 are transmitting ports of the independent circuit module 41, 411 and 412 are transceiving ports, 411 and 412 are respectively connected to 2 first T ports of the multi-way switch 10, and 413, 414, 415, and 416 are receiving ports of the independent circuit module 41, and are respectively connected to 4 second T ports of the multi-way switch 10 in a one-to-one correspondence manner. As can be seen from fig. 7, the total number of ports of the independent circuit module 41 is equal to the total number of ports of all the signal processing circuits integrated in the independent circuit module 41, and has a corresponding connection relationship. For example, 420 is connected to the first transmitting port of the first transceiving processing circuit 321, 421 is connected to the first receiving port of the first transceiving processing circuit 321, 411 is connected to the transmitting/receiving port of the first transceiving processing circuit 321, 422 is connected to the second transmitting port of the first transceiving processing circuit 321, 423 is connected to the second receiving port of the first transceiving processing circuit 321, and 412 is connected to the transmitting/receiving port of the second transceiving processing circuit 322. 425. 427 are connected to the two receiving ports of the second transceiving signal processing circuit 322, 424 and 426 are connected to the two transmitting ports of the second transceiving signal processing circuit 322, and 413 is connected to the receiving port of the first receiving signal processing circuit 331. 428 is connected to the transmission port of the first received signal processing circuit 331, and 413 is connected to the reception port of the first received signal processing circuit 331. 429 is connected to the transmit port of the second receive signal processing circuit 332 and 414 is connected to the receive port of the second receive signal processing circuit 332. 430 is connected to the transmission port of the third received signal processing circuit 333, and 415 is connected to the reception port of the third received signal processing circuit 333. 431 is connected to the transmit port of the fourth receive signal processing circuit 334 and 416 is connected to the receive port of the fourth receive signal processing circuit 334.

In the embodiment of the present application, the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322 and the 4 receiving signal processing circuits are integrated in 1 independent circuit module, so as to improve the integration level of the radio frequency circuit, reduce the number of the independent circuit modules, improve the space utilization rate of the electronic device, and facilitate the improvement of the adaptation flexibility and the reduction of the cost.

Alternatively, the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322 and the 4 receiving signal processing circuits in the radio frequency circuit 30 in fig. 4 may be integrated into 2 independent circuit modules. The 2 independent circuit modules are respectively a first independent circuit module and a second independent circuit module; the first independent circuit module at least comprises a first transceiving signal processing circuit 321 and a second transceiving signal processing circuit 322; the second independent circuit block includes at least 2 of the 4 received signal processing circuits.

Please refer to fig. 8. Fig. 8 is a schematic structural diagram of another rf circuit integrated in a separate circuit module according to an embodiment of the present application. As shown in fig. 8, the first transmission/reception signal processing circuit 321 and the second transmission/reception signal processing circuit 322 are integrated in the first independent circuit module 51, and the first reception signal processing circuit 331, the second reception signal processing circuit 332, the third reception signal processing circuit 333, and the fourth reception signal processing circuit 334 are integrated in the second independent circuit module 52. The first independent circuit module 51 includes 4 receiving ports (521, 523, 525, 527 shown in fig. 8) and 4 transmitting ports (520, 522, 524, 526 shown in fig. 8) and 2 transceiving ports (511, 512 shown in fig. 8), where 521, 523, 525, 527 are connected to the transmitting ports corresponding to the radio frequency transceivers 31, 520, 522, 524, 526 are connected to the receiving ports corresponding to the radio frequency transceivers 31, 511 is connected to the first T port of the multi-way selector switch 10, and 512 is connected to the other first T port of the multi-way selector switch 10. The second independent circuit module 52 includes 4 receiving ports (513, 514, 515, 516) and 4 transmitting ports (528, 529, 530, 531), where 513, 514, 515, 516 are respectively connected to the 4 second T ports of the multiplexer 10 in a one-to-one correspondence, and 528, 529, 530, 531 are respectively connected to the receiving ports corresponding to the radio frequency transceiver 31. Wherein, all ports of all independent modules are not connected with each other.

As can be seen from fig. 8, the total number of ports of the first independent circuit module 51 is equal to the total number of ports of all the signal processing circuits integrated in the first independent circuit module 51, and has a corresponding connection relationship. The total number of ports of the second independent circuit module 52 is equal to the total number of ports of all the signal processing circuits integrated in the second independent circuit module 52, and has a corresponding connection relationship.

It should be noted that the integration manner in fig. 8 is only one possible implementation manner, and on the premise that the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322, and the 3 receiving signal processing circuits are integrated into 2 independent circuit modules, as long as "the first independent circuit module at least includes the first transceiving signal processing circuit and the second transceiving signal processing circuit; the second independent circuit block may include at least 2 "of the 4 received signal processing circuits.

In the embodiment of the present application, the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322 and the 4 receiving signal processing circuits are integrated in 2 independent circuit modules, so as to improve the integration level of the radio frequency circuit, reduce the number of the independent circuit modules, improve the space utilization rate of the electronic device, and facilitate the improvement of the adaptation flexibility and the reduction of the cost.

Alternatively, the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322 and the 4 receiving signal processing circuits in the radio frequency circuit 30 in fig. 4 may be integrated into 3 independent circuit modules.

The 3 independent circuit modules are respectively a first independent circuit module, a second independent circuit module and a third independent circuit module; the first independent circuit module includes 2 transceiving signal processing circuits, and the second and third independent circuit modules each include 2 of 4 receiving signal processing circuits.

Please refer to fig. 9. Fig. 9 is a schematic structural diagram of another rf circuit integrated in a separate circuit module according to an embodiment of the present application. As shown in fig. 9, the first transmission/reception signal processing circuit 321 and the second transmission/reception signal processing circuit 322 are integrated in the first independent circuit module 61, the first reception signal processing circuit 331 and the second reception signal processing circuit 332 are integrated in the second independent circuit module 62, and the third reception signal processing circuit 333 and the fourth reception signal processing circuit 334 are integrated in the third independent circuit module 63. The first independent circuit module 61 includes 4 receiving ports (e.g. 621, 623, 625, 627 shown in fig. 9), 4 transmitting ports (e.g. 620, 622, 624, 626 shown in fig. 9) and 2 transceiving ports (e.g. 611, 612 shown in fig. 9), the 621, 623, 625, 627 are connected to the transmitting port corresponding to the rf transceiver 31, the 620, 622, 624, 626 are connected to the receiving port corresponding to the rf transceiver 31, the 611 is connected to the first T port of the multiplexer 10, and the 612 is connected to the other first T port of the multiplexer 10. The second independent circuit module 62 includes 2 receive ports (613, 614 shown in fig. 9) and 2 transmit ports (628, 629 shown in fig. 9), and the third independent circuit module 63 includes 2 receive ports (615, 616 shown in fig. 9) and 2 transmit ports (630, 631 shown in fig. 9). 613, 614, 615 and 616 are respectively connected to the 4 second T ports of the multiplexer 10 in a one-to-one correspondence manner, and 628, 629, 630 and 631 are respectively connected to the receiving ports corresponding to the rf transceiver 31. Wherein, all ports of all independent modules are not connected with each other.

As can be seen from fig. 9, the total number of ports of the first independent circuit module 61 is equal to the total number of ports of all the signal processing circuits integrated in the first independent circuit module 61, and has a corresponding connection relationship. The total number of ports of the second independent circuit module 62 is equal to the total number of ports of all the signal processing circuits integrated in the second independent circuit module 62, and has a corresponding connection relationship. The total number of ports of the third independent circuit module 63 is equal to the total number of ports of all the signal processing circuits integrated in the third independent circuit module 63, and has a corresponding connection relationship.

In the embodiment of the present application, the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322, and the 4 receiving signal processing circuits are integrated into 3 independent circuit modules.

Among the 4 independent circuit modules, 3 independent circuit modules (such as the second independent circuit module 62 and the third independent circuit module 63 shown in fig. 9) have the same circuit structure, so that the reusability of the independent circuit modules can be improved, the batch production of the independent circuit modules is facilitated, the adaptation flexibility is improved, and the cost is reduced.

Alternatively, the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322 and the 4 receiving signal processing circuits in the radio frequency circuit 30 in fig. 4 may be integrated into 4 independent circuit modules.

The 4 independent circuit modules are respectively a first independent circuit module, a second independent circuit module, a third independent circuit module and a fourth independent circuit module; the first independent circuit module comprises a first receiving and transmitting signal processing circuit, and the second independent circuit module comprises a second receiving and transmitting signal processing circuit; the third independent circuit block and the fourth independent circuit block each include 2 of the 4 received signal processing circuits.

Please refer to fig. 10. Fig. 10 is a schematic structural diagram of another rf circuit integrated in a separate circuit module according to an embodiment of the present application. As shown in fig. 10, the first transceiving signal processing circuit 321 is integrated in the first independent circuit module 71; the second transceiving signal processing circuit 322 is integrated in the second independent circuit module 72; the first received signal processing circuit 331 and the second received signal processing circuit 332 are integrated in the third independent circuit module 73; the third received signal processing circuit 333 and the fourth received signal processing circuit 334 are integrated in the fourth independent circuit module 74. The first independent circuit module 71 includes 2 receiving ports (e.g., 721 and 723 shown in fig. 10), 2 transmitting ports (e.g., 720 and 722 shown in fig. 10), and 1 transceiving port (e.g., 711 shown in fig. 10), where the 721 and 723 are connected to the transmitting ports corresponding to the rf transceivers 31, the 720 and 722 are connected to the receiving ports corresponding to the rf transceivers 31, and the 711 is connected to a first T port of the multiplexer 10. The second independent circuit module 72 includes 2 receiving ports (725, 727 shown in fig. 10) and 2 transmitting ports (724, 726 shown in fig. 10) and 1 transceiving port (712 shown in fig. 10), 725 and 727 are connected to the corresponding transmitting ports of the rf transceiver 31, 724 and 726 are connected to the corresponding receiving ports of the rf transceiver 31, and 712 is connected to the other first T port of the multiplexer 10. The third independent circuit module 73 includes 2 receive ports (713, 714 shown in fig. 10) and 2 transmit ports (728, 729 shown in fig. 10), and the fourth independent circuit module 74 includes 2 receive ports (715, 716 shown in fig. 10) and 2 transmit ports (730, 731 shown in fig. 10). 713, 714, 715 and 716 are respectively connected to the 4 second T ports of the multiplexer 10 in a one-to-one correspondence manner, and 728, 729, 730 and 731 are respectively connected to the receiving ports corresponding to the rf transceiver 31. Wherein, all ports of all independent modules are not connected with each other.

As can be seen from fig. 10, the total number of ports of the first independent circuit module 71 is equal to the total number of ports of all the signal processing circuits integrated in the first independent circuit module 71, and has a corresponding connection relationship. The total number of ports of the second independent circuit module 72 is equal to the total number of ports of all the signal processing circuits integrated in the second independent circuit module 72, and has a corresponding connection relationship. The total number of ports of the third independent circuit module 73 is equal to the total number of ports of all the signal processing circuits integrated in the third independent circuit module 73, and has a corresponding connection relationship. The total number of ports of the fourth independent circuit module 74 is equal to the total number of ports of all the signal processing circuits integrated in the fourth independent circuit module 74, and has a corresponding connection relationship.

In the embodiment of the present application, the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322, and the 4 receiving signal processing circuits are integrated in 4 independent circuit modules, the first independent circuit module 71 and the second independent circuit module 72 have the same circuit structure, the third independent circuit module 73 and the fourth independent circuit module 74 have the same circuit structure, the reusability of the independent circuit modules can be improved, the mass production of the independent circuit modules is facilitated, the adaptation flexibility is improved, and the cost is reduced.

Alternatively, the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322 and the 4 receiving signal processing circuits in the radio frequency circuit 30 in fig. 4 may be integrated into 5 independent circuit modules.

The 5 independent circuit modules are respectively a first independent circuit module, a second independent circuit module, a third independent circuit module, a fourth independent circuit module and a fifth independent circuit module; the first independent circuit module comprises a first transceiving signal processing circuit and a second transceiving signal processing circuit; the second independent circuit module, the third independent circuit module, the fourth independent circuit module and the fifth independent circuit module each include 1 of the 4 received signal processing circuits. Please refer to fig. 11. Fig. 11 is a schematic structural diagram of another rf circuit integrated in a separate circuit module according to an embodiment of the present application. As shown in fig. 11, the first transceiving signal processing circuit 321 and the second transceiving signal processing circuit 322 are integrated in the first independent circuit module 81; the first received signal processing circuit 331 is integrated in the second independent circuit module 82; the second received signal processing circuit 332 is integrated in the third independent circuit module 83; the third received signal processing circuit 333 is integrated in the fourth independent circuit module 84; the fourth received signal processing circuit 334 is integrated in the fifth independent circuit block 85. The first independent circuit module 81 includes 4 receiving ports (821, 823, 825, 827 shown in fig. 11), 4 transmitting ports (820, 822, 824, 828 shown in fig. 11) and 2 transceiving ports (811, 812 shown in fig. 11), 821, 823, 825, 827 are connected to the transmitting ports corresponding to the rf transceivers 31, 820, 822, 824, 826 are connected to the receiving ports corresponding to the rf transceivers 31, 811 is connected to the first T port of the multiplexer 10, and 812 is connected to the other first T port of the multiplexer 10. The second independent circuit module 82 includes 1 receive port (813 in fig. 11) and 1 transmit port (828 in fig. 11); the third independent circuit module 83 includes 1 receiving port (814 shown in fig. 11) and 1 transmitting port (829 shown in fig. 11); the fourth independent circuit module 84 includes 1 receive port (815 shown in fig. 11) and 1 transmit port (830 shown in fig. 11); the fifth independent circuit module 85 includes 1 receiving port (816 shown in fig. 11) and 1 transmitting port (831 shown in fig. 11); 713, 714, 715 and 716 are respectively connected to the 4 second T ports of the multiplexer 10 in a one-to-one correspondence manner, and 728, 729, 730 and 731 are respectively connected to the receiving ports corresponding to the rf transceiver 31. Wherein, all ports of all independent modules are not connected with each other.

As can be seen from fig. 11, the total number of ports of the first independent circuit block 81 is equal to the total number of ports of all the signal processing circuits integrated in the first independent circuit block 81, and has a corresponding connection relationship. The total number of ports of the second independent circuit module 82 is equal to the total number of ports of all the signal processing circuits integrated in the second independent circuit module 82, and has a corresponding connection relationship. The total number of ports of the third independent circuit block 83 is equal to the total number of ports of all the signal processing circuits integrated in the third independent circuit block 83, and has a corresponding connection relationship. The total number of ports of the fourth independent circuit module 84 is equal to the total number of ports of all the signal processing circuits integrated in the fourth independent circuit module 84, and has a corresponding connection relationship. The total number of ports of the fifth independent circuit module 85 is equal to the total number of ports of all the signal processing circuits integrated in the fifth independent circuit module 85, and has a corresponding connection relationship.

In the embodiment of the present application, the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322, and the 4 receiving signal processing circuits are integrated in 5 independent circuit modules, the second independent circuit module 82 and the fourth independent circuit module 84 in the 5 independent circuit modules have the same circuit structure, the third independent circuit module 83 and the fifth independent circuit module 85 have the same circuit structure, the reusability of the independent circuit modules can be improved, the mass production of the independent circuit modules is facilitated, the adaptation flexibility is improved, and the cost is reduced.

Alternatively, the first transceiving signal processing circuit 321, the second transceiving signal processing circuit 322 and the 4 receiving signal processing circuits in the radio frequency circuit 30 in fig. 4 may be integrated into 6 independent circuit modules. The 6 independent circuit modules are respectively integrated with one of the first transmit/receive signal processing circuit 321, the second transmit/receive signal processing circuit 322, the first receive signal processing circuit 331, the second receive signal processing circuit 332, the third receive signal processing circuit 333, and the fourth receive signal processing circuit 334. Because the first receiving and transmitting signal processing circuit 321 and the second receiving and transmitting signal processing circuit 322 have the same circuit structure, the first receiving and transmitting signal processing circuit 321 and the third receiving signal processing circuit 333 have the same circuit structure, the second receiving signal processing circuit 332 and the fourth receiving signal processing circuit 334 have the same circuit structure, the reusability of the independent circuit module can be improved, the batch production of the independent circuit module is facilitated, the adaptation flexibility is improved, and the cost is reduced.

In one possible example, the 4 antennas include a first antenna, a second antenna, a third antenna, and a fourth antenna, and the first antenna, the second antenna, the third antenna, and the fourth antenna are all antennas supporting a 5G NR frequency band.

The 5G NR frequency band may include, for example, 3.3GHz-3.8GHz, and 4.4GHz-5 GHz.

In one possible example, the 4 antennas include a first antenna, a second antenna, a third antenna, and a fourth antenna, the first antenna and the fourth antenna are antennas supporting an LTE band and a 5G NR band, and the second antenna and the third antenna are antennas supporting only a 5G NR band.

Wherein, the first and the fourth antennas are used for supporting DL 4x4MIMO of individual frequency bands on the LTE terminal. Its 2 receiving antennas are shared with the 5G NR antennas. The LTE frequency bands may include, for example, 1880-1920MHz, 2496-2690 MHz.

In one possible example, as shown in fig. 12, the antenna system further includes a first combiner and a second combiner, where a first port of the first combiner is used to connect the first antenna, a second port of the first combiner is used to connect a first receiving path in LTE4x4MIMO of the electronic device, and a third port of the first combiner is used to connect a corresponding P port in the multi-way selector switch; a first port of the second combiner is used for connecting the fourth antenna, a second port of the second combiner is used for connecting a second receiving channel in LTE4x4MIMO of the electronic device, and a third port of the second combiner is used for connecting a corresponding P port in the multi-path selector switch.

The LTE4 × 4MIMO is a downlink LTE receiving circuit, and may be defined as a third receiving path. Since LTE currently has 2 receptions. When LTE4x4MIMO is supported, third and fourth receive channels may be added.

The electronic device can reserve 1 antenna with better performance to a main set receiving PRX in the circuit for standby use according to the actual condition of 4 antennas, and the first T port in the switch has a receiving and transmitting function, namely, the first T port can perform TX and PRX functions and can switch the antennas at will, so that the limitation of connecting ports of a shared antenna at the position is not needed.

In one possible example, as shown in fig. 13, the antenna system further includes a first SPDT switch and a second SPDT switch, wherein a first port of the first SPDT switch is configured to connect to the first antenna, a second port of the first SPDT switch is configured to connect to a first receive path in LTE4x4MIMO of the electronic device, and a third port of the first SPDT switch is configured to connect to a corresponding P port in the multi-way selection switch; the first port of the second SPDT switch is configured to be connected to the fourth antenna, the second port of the second SPDT switch is configured to be connected to a second receiving path in the LTE4x4MIMO of the electronic device, and the third port of the second SPDT switch is configured to be connected to a corresponding P port in the multiplexer switch.

Referring to fig. 14, fig. 14 is a schematic flow chart of a function control method disclosed in an embodiment of the present application, which is applied to an electronic device, where the electronic device includes an antenna system, a radio frequency circuit, and a multi-way selection switch, the multi-way selection switch includes 6T ports and 4P ports, the 6T ports include 2 first T ports and 4 second T ports, the electronic device supports a dual-frequency dual transmission mode, each first T port is fully connected to 4P ports, each second T port is connected to 3P ports of the 4P ports, the P ports connected to a plurality of second T ports supporting a signal receiving function of a same frequency band cover the 4P ports, and the P ports connected to each T port of the 4T ports in a signal receiving state are different from each other; the method comprises the following steps.

1401, the electronic device determines to perform a preset function, where the preset function includes a first function and a second function, the first function is a function of supporting alternate transmission of sounding reference signals SRS between transmitting antennas in a single transmission mode and transmitting 4-port SRS, and the second function is a function of supporting 4 antennas to receive data simultaneously.

1402, in the process of starting the first function, the electronic device adjusts the matching state between 3T ports and 4P ports currently occupied by the single frequency band where the second function is located according to the P port currently occupied by the single frequency band where the first function is located.

Specifically, the 3T ports may be 4 second T ports except for the first T port among the 4T ports.

The dual-frequency dual-transmission mode means that the electronic equipment can support transmission and reception of two frequency bands, but only can allow two-way transmission and 4-way reception of one frequency band in the same time period.

Specifically, the implementation method of the step 1402 may specifically be:

when the first function is realized, determining 1P port occupied by 1 first T port supporting the first function, and determining 3P ports occupied by 4 second T ports supporting the second function; if the 3P ports include the 1P port, a second T port occupying the 1P port is switched to another P port.

The electronic equipment executes the first and second functions and can meet the function requirements in a 5G NR FDD system.

Therefore, in the embodiment of the application, the electronic device can realize the preset function in the 5G NR FDD system through the radio frequency system constructed based on the multi-way selection switch, and the multi-way selection switch is simplified in structure and high in control efficiency, so that the real-time performance and the efficiency of the electronic device for completing the preset function are improved.

The following describes in detail the switching process between the T port and the P port in the embodiment of the present application, taking the multiway switch shown in fig. 2 as an example. Since the 5G NR protocol currently defines that 4P ports can only operate in the same frequency band in the same time period, although the electronic device of the present application supports a dual-frequency dual transmission mode, an SRS process in the same time period only detects one frequency band, it is assumed herein that an Nx frequency band is detected, and it is assumed that 4T ports (a T1 port, a T3 port, a T4 port, and a T5 port) of the Nx frequency band in an initial state of the multi-way switch are sequentially connected to the 4P ports, that is, a first T port T1 of the 4T ports is connected to P1, a second T port T2 is connected to P2, a third T port T3 is connected to P3, and a fifth T port T5 is connected to P4, because the dual-frequency dual transmission mode is supported, two antennas can transmit in one detection period, so that 4 antennas need to be polled and a detection period needs to be 2; 4P ports are respectively connected with 4 antennas. When the electronic device determines that the SRS is enabled, since the electronic device supports the dual-frequency dual transmission mode, only one antenna transmits in one sounding period.

For example, in the first probing period, the electronic device may transmit and receive signals through the T1 and P1 paths (which are turned on in advance to be used as the transceiving paths) to perform the Nx band signal reception and the first antenna channel quality detection in the first probing period, and may also transmit and receive signals through the T2 and P2 paths (which are turned on in advance to be used as the transceiving paths) to perform the Nx band signal reception and the second antenna channel quality detection in the first probing period, since the P ports corresponding to T3 and T5 are not occupied by T1 and T2, the multi-way switch does not need to be switched in the first probing period.

In the second probing period, the electronic device may control T1 to switch from the initial state connection P1 to the connection P3 in the second probing period, so that T1 and P3 conduct transceiving Nx band signals for signal reception and channel quality probing of the third antenna, and may control T2 to switch from the initial state connection P2 to the connection P4 in the second probing period, so that T2 and P4 conduct transceiving Nx band signals for signal reception and channel quality probing of the fourth antenna, and since P3 corresponding to T3 is occupied by T1, in order to maintain the signal receiving function of T3, after the first probing period ends and before the second probing period starts, the multiplexer switches T3 to connect to P2, and switches T5 to P1.

To this end, the electronic device completes the SRS detection process, and T1 is connected to P3 for signal reception, T2 is connected to P4 for signal reception, T3 is connected to P2 for signal reception, and T5 is connected to P1 for signal reception.

The channel quality detection for the Ny frequency band is similar to the channel quality detection for the Nx frequency band, and is not described herein again.

Referring to fig. 15, fig. 15 is a schematic structural diagram of a radio frequency system disclosed in an embodiment of the present application, where the radio frequency system includes an antenna system 20, a radio frequency circuit 30, and the multi-way selector switch 10 according to any of the embodiments;

the multi-way selector switch 10 is configured to connect the radio frequency circuit 30 and the antenna system 20 to implement a preset function of the electronic device 100 in the frequency division multiplexing FDD system, where the preset function includes a first function and a second function, the first function is to support alternate transmission and transmission of the SRS at 4 ports between the transmitting antennas through the SRS, and the second function is to support simultaneous data reception of 4 antennas.

Referring to fig. 16, fig. 16 is a schematic structural diagram of an electronic device disclosed in an embodiment of the present application, where the electronic device 100 includes an antenna system 20, a radio frequency circuit 30, and the multi-way selector switch 10 according to any of the embodiments;

the multi-way selector switch 10 is configured to connect the radio frequency circuit 30 and the antenna system 20 to implement a preset function of the electronic device 100, where the preset function includes a first function and a second function, the first function is to support alternate transmission of the SRS between the transmitting antennas through the sounding reference signal SRS and to transmit the 4-port SRS, and the second function is to support simultaneous data reception of the 4 antennas.

In addition, as shown in fig. 17, 4 antennas in the antenna system described in the embodiment of the present application may also be multiplexed by a wireless charging receiver of the electronic device, specifically, the wireless charging receiver comprises a receiving antenna and a receiving control circuit, wherein the receiving antenna is matched with a transmitting antenna of a wireless charging transmitter (under the condition of same or similar frequency, the receiving antenna resonates, energy is transmitted in a wireless transmission mode in a radiation resonant magnetic coupling mode), the receiving control circuit converts the energy into direct current DC through a loop array antenna and outputs the direct current DC to a battery for charging, the receiving control circuit can dynamically adjust the frequency of the loop array antenna, and matching the frequency with the transmitting antenna of the wireless charging transmitter to realize the pairing charging, or, the wireless charging transmitter is interacted with the frequency variation range in real time to realize an exclusive encryption wireless charging mode.

The receiving antenna may be an antenna composed of at least 1 antenna of 4 antennas (in many cases, the antennas are gated by a switch).

For example: as shown in fig. 18, the receiving antenna is a loop array antenna formed by the above-mentioned 4 antennas, the 4 antennas specifically include an antenna 1, an antenna 2, an antenna 3, and an antenna 4, where the antenna 1 and the antenna 4 support LTE and 5G NR frequency bands, the antenna 2 and the antenna 3 support only 5G NR frequency band, a port of the antenna 1 and a port of the antenna 4 are used as ports of the loop array antenna, where adjacent antennas are connected by a gating circuit 170 having an isolation function, the gating circuit 170 includes a spacer 171 and a switch 172, the spacer 171 is a conductor, the switch 172 is further connected to a controller, and the electronic device can communicate with the switch 172 of each gating circuit 170 in a wireless charging mode to form a loop array antenna to receive energy. By adding the spacer 171 between the antennas, the gating circuit 170 reduces mutual coupling between multiple antennas of the electronic device in a normal communication mode, improves isolation between the multiple antennas, optimizes antenna performance, and can connect the multiple antennas in series to form a loop array antenna through the switch 171, so that the transmitting antenna can be better matched to transmit energy, and in addition, because the capabilities of the antenna 1 and the antenna 4 are stronger than those of the antenna 2 and the antenna 3, the loop array antenna can reduce energy transmission loss as much as possible.

The foregoing is an implementation of the embodiments of the present application, and it should be noted that, for those skilled in the art, several modifications and decorations can be made without departing from the principle of the embodiments of the present application, and these modifications and decorations are also regarded as the protection scope of the present application.

Claims (20)

1. A multi-way selection switch is applied to wireless communication equipment, the wireless communication equipment comprises an antenna system and a radio frequency circuit, the wireless communication equipment supports a dual-frequency dual-transmission mode, and the antenna system comprises 4 antennas;

the multi-way selector switch comprises 6T ports and 4P ports, wherein the 6T ports comprise 2 first T ports and 4 second T ports; each first T port is fully connected with the 4P ports, each second T port is connected with 3P ports in the 4P ports, the P ports connected with the plurality of second T ports supporting the signal receiving function of the same frequency band cover the 4P ports, and the P ports connected with each T port in the 4T ports in the signal receiving state are different from each other;

the multi-path selection switch is used for connecting the radio frequency circuit and the antenna system to realize the preset function of the wireless communication equipment in a frequency division multiplexing FDD mode, the preset function comprises a first function and a second function, the first function is a function of supporting alternate sending of SRS between transmitting antennas and sending of 4-port SRS, and the second function is a function of supporting simultaneous data receiving of the 4 antennas;

in the process of starting the first function, the matching state between the 3T ports currently occupied by the second function and the 4P ports is adjusted according to the P port currently occupied by the first function.

2. The multiplexing switch of claim 1, wherein the 4 second T ports are T ports for reception of a first frequency band or reception of a second frequency band, and the first frequency band and the second frequency band do not overlap; the 4P ports are connected with the 4 antennas in a one-to-one corresponding mode; the 2 first T ports are T ports for first frequency band reception and second frequency band reception.

3. The multi-way selection switch of claim 2, wherein the multi-way selection switch comprises 60 first switching tubes, 6 second switching tubes and 4 third switching tubes, the second switching tubes correspond to the T ports, the third switching tubes correspond to the P ports, every 3 first switching tubes are connected in series to form a switching subunit between the T ports and the P ports, 2 first switching tubes at two ends of the switching subunit are respectively connected with 1T port and 1P port, the first switching tube in the middle of the switching subunit is grounded, and the gate of each first switching tube, each second switching tube and each third switching tube is connected with a switch control chip.

4. The multiplexing switch of claim 3, wherein the first switch tube, the second switch tube, and the third switch tube each comprise a field effect transistor.

5. The multiplexing switch of claim 2, wherein the radio frequency circuit includes a radio frequency transceiver, 2 transceiver signal processing circuits, and 4 receive signal processing circuits; the receiving and transmitting signal processing circuit is formed by coupling a transmitting path supporting the transmission of the first frequency band, a receiving path supporting the receiving of the first frequency band, a transmitting path supporting the transmission of the second frequency band and a receiving path supporting the receiving of the second frequency band; the 4 received signal processing circuits include 2 received signal processing circuits supporting reception in the first frequency band and 2 received signal processing circuits supporting reception in the second frequency band.

6. The multiplexing switch of claim 5, wherein the 2 transceiver signal processing circuits and the 4 receive signal processing circuits are integrated in 1 independent circuit module.

7. The multiplexing switch of claim 5, wherein said 2 transceiver signal processing circuits and said 4 receive signal processing circuits are integrated in 2 independent circuit modules;

the 2 independent circuit modules are respectively a first independent circuit module and a second independent circuit module; the first independent circuit module comprises at least the 2 transceiving signal processing circuits; the second independent circuit block includes at least 2 of the 4 received signal processing circuits.

8. The multiplexing switch of claim 5, wherein said 2 transceiver signal processing circuits and said 4 receive signal processing circuits are integrated in 3 independent circuit modules;

the 3 independent circuit modules are respectively a first independent circuit module, a second independent circuit module and a third independent circuit module; the first independent circuit module includes the 2 transceive signal processing circuits, and the second and third independent circuit modules each include 2 of the 4 receive signal processing circuits.

9. The multiplexing switch of claim 5, wherein said 2 transceiver signal processing circuits and said 4 receive signal processing circuits are integrated in 4 independent circuit modules;

the 4 independent circuit modules are respectively a first independent circuit module, a second independent circuit module, a third independent circuit module and a fourth independent circuit module; the first and second independent circuit modules each comprise 1 of the 2 transceive signal processing circuits; the third independent circuit block and the fourth independent circuit block each include 2 of the 4 received signal processing circuits.

10. The multiplexing switch of claim 5, wherein said 2 transceiver signal processing circuits and said 4 receive signal processing circuits are integrated in 5 independent circuit modules;

the 5 independent circuit modules are respectively a first independent circuit module, a second independent circuit module, a third independent circuit module, a fourth independent circuit module and a fifth independent circuit module; the first independent circuit module includes the 2 transceiving signal processing circuits, and the second, third, fourth and fifth independent circuit modules each include 1 of the 4 receiving signal processing circuits.

11. The multiplexing switch of claim 5, wherein said 2 transmit-receive signal processing circuits and said 4 receive signal processing circuits are integrated in 6 independent circuit modules.

12. The multiplexing switch according to any of claims 5-11, wherein the first transceiving signal processing circuit is any of the 2 transceiving signal processing circuits;

the first transceiving signal processing circuit comprises a first power amplifier supporting the first frequency band, a second power amplifier supporting the second frequency band, a first low noise amplifier supporting the first frequency band, a second low noise amplifier supporting the second frequency band, a first duplexer, a second duplexer, a first coupler and a first selection switch, wherein an input port of the first power amplifier and an input port of the second power amplifier are respectively connected with corresponding transmitting ports in the radio frequency transceiver, an output port of the first low noise amplifier and an output port of the second low noise amplifier are respectively connected with corresponding receiving ports in the radio frequency transceiver, an output port of the first power amplifier is connected with a signal receiving port of the first duplexer, an input port of the first low noise amplifier is connected with a signal transmitting port of the first duplexer, the receiving and transmitting shared port of the first duplexer is connected with the first port of the first coupler; an output port of the second power amplifier is connected with a signal receiving port of the second duplexer, an input port of the second low noise amplifier is connected with a signal transmitting port of the second duplexer, and a transmitting-receiving common port of the second duplexer is connected with a second port of the first coupler; the third port of the first coupler is connected with the first fixed port of the first selector switch, the fourth port of the first coupler is connected with the second fixed port of the first selector switch, and the selection port of the first selector switch is connected with one of the 2 first T ports.

13. A multi-way selector switch according to any of claims 5-11,

the receiving signal processing circuit supporting the receiving of the first frequency band comprises a low noise amplifier supporting the first frequency band and a filter supporting the passing of the first frequency band; an output port of the low noise amplifier supporting the first frequency band is connected to a corresponding receiving port for receiving the first frequency band in the radio frequency transceiver, an input port of the low noise amplifier supporting the first frequency band is connected to an output port of the filter supporting the first frequency band to pass through, and an input port of the filter supporting the first frequency band to pass through is connected to a T port for receiving the first frequency band in the 4 second T ports;

the receiving signal processing circuit supporting the receiving of the second frequency band comprises a low noise amplifier supporting the second frequency band and a filter supporting the passing of the second frequency band; the output port of the low noise amplifier supporting the second frequency band is connected to a corresponding receiving port used for receiving the second frequency band in the radio frequency transceiver, the input port of the low noise amplifier supporting the second frequency band is connected to the output port of the filter supporting the passing of the second frequency band, and the input port of the filter supporting the passing of the second frequency band is connected to the T port used for receiving the second frequency band in the 4 second T ports.

14. The multi-way switch according to any of claims 1-11, wherein said 4 antennas comprise a first antenna, a second antenna, a third antenna and a fourth antenna, and wherein said first antenna, said second antenna, said third antenna and said fourth antenna are all antennas supporting a fifth generation new air interface 5G NR frequency band.

15. The multi-way selection switch of any one of claims 1-11, wherein the 4 antennas comprise a first antenna, a second antenna, a third antenna and a fourth antenna, the first antenna and the fourth antenna are antennas supporting LTE band and 5G NR band, and the second antenna and the third antenna are antennas supporting only 5G NR band.

16. The multi-way selection switch of claim 15, wherein the antenna system further comprises a first combiner and a second combiner, wherein a first port of the first combiner is configured to connect to the first antenna, a second port of the first combiner is configured to connect to a first receive path in LTE4x4MIMO of the wireless communication device, and a third port of the first combiner is configured to connect to a corresponding P port in the multi-way selection switch; a first port of the second combiner is configured to be connected to the fourth antenna, a second port of the second combiner is configured to be connected to a second receiving path in LTE4x4MIMO of the wireless communication device, and a third port of the second combiner is configured to be connected to a corresponding P port in the multiplexer.

17. The multiplexing switch of claim 15, wherein the antenna system further comprises a first Single Pole Double Throw (SPDT) switch and a second SPDT switch, wherein a first port of the first SPDT switch is configured to connect to the first antenna, a second port of the first SPDT switch is configured to connect to a first receive path in LTE4x4MIMO of the wireless communication device, and a third port of the first SPDT switch is configured to connect to a corresponding P port in the multiplexing switch; the first port of the second SPDT switch is configured to be connected to the fourth antenna, the second port of the second SPDT switch is configured to be connected to a second receiving path in LTE4x4MIMO of the wireless communication device, and the third port of the second SPDT switch is configured to be connected to a corresponding P port in the multiplexer switch.

18. A function control method is applied to a wireless communication device, the wireless communication device comprises an antenna system, a radio frequency circuit and a multi-way selection switch, the antenna system comprises 4 antennas, the wireless communication device supports a dual-frequency dual-transmission mode, the multi-way selection switch comprises 6T ports and 4P ports, the 6T ports comprise 2 first T ports and 4 second T ports, each first T port is fully connected with the 4P ports, each second T port is connected with 3P ports in the 4P ports, the P ports connected with a plurality of second T ports supporting signal receiving functions of the same frequency band cover the 4P ports, and the P ports connected with each T port in the 4T ports in a signal receiving state are different from each other; the method comprises the following steps:

the wireless communication equipment determines to execute a preset function, wherein the preset function comprises a first function and a second function, the first function is a function of supporting alternate transmission of a Sounding Reference Signal (SRS) among transmitting antennas and transmitting a 4-port SRS, and the second function is a function of supporting the 4 antennas to simultaneously receive data;

and in the process of starting the first function, the wireless communication equipment adjusts the matching states between the 3T ports and the 4P ports currently occupied by the second function according to the P port currently occupied by the first function.

19. A radio frequency system comprising an antenna system, radio frequency circuitry and a multiplexer switch as claimed in any one of claims 1 to 17.

20. A wireless communication device comprising an antenna system, radio frequency circuitry, and a multiplexing switch according to any of claims 1-17;

the wireless communication device includes at least any one of: electronic equipment, base station.

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