CN209057208U - Receiving module and Related product - Google Patents
Receiving module and Related product Download PDFInfo
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- CN209057208U CN209057208U CN201821172435.4U CN201821172435U CN209057208U CN 209057208 U CN209057208 U CN 209057208U CN 201821172435 U CN201821172435 U CN 201821172435U CN 209057208 U CN209057208 U CN 209057208U
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Abstract
The embodiment of the present application discloses a kind of receiving module and Related product, including at least signal receiving channel, the first switching switch, the second switching switch all the way;First switching switch connection at least signal receiving channel all the way, at least the second switching of signal receiving channel connection switchs all the way, first switching switch or the second switching switch include that n1Pn2T is switched, and every road signal receiving channel includes filter Filter and low-noise amplifier LNA, LNA connection Filter;First switching switchs the antenna for connecting the corresponding antenna sets of receiving module, and the second switching switch is for connecting emitting mould train and/or RF transceiver, and receiving module is arranged close to antenna sets, and n1 is positive integer, and n2 is the integer more than or equal to 2.The embodiment of the present application advantageously reduces radio frequency link Insertion Loss, promotes each channel sensitivity, builds compared to discrete device, and integrated level is higher, and area/cost/power consumption is more excellent.
Description
Technical field
This application involves technical field of mobile terminals, and in particular to a kind of receiving module and Related product.
Background technique
With a large amount of popularization and applications of the electronic equipments such as smart phone, smart phone can support using more and more,
Function is stronger and stronger, and smart phone develops towards diversification, personalized direction, becomes indispensable electricity in user's life
Sub- articles.Electronic equipment generally uses single antenna or double antenna radio frequency system framework in forth generation 4G mobile communication system, at present
5th generation 5G mobile communication system newly eats dishes without rice or wine to propose to support the radio frequency system framework demand of 4 antenna sets in NR system.
Summary of the invention
The embodiment of the present application provides a kind of receiving module and Related product, to promote each channel sensitivity, compared to point
It is built from device, integrated level is higher, and area/cost/power consumption is more excellent.
In a first aspect, the embodiment of the present application provides a kind of receiving module, including at least signal receiving channel, first cut all the way
Change switch, the second switching switch;
The first switching switch connection at least signal receiving channel all the way, at least signal receiving channel all the way
The second switching switch is connected, the first switching switch or the second switching switch include that n1Pn2T is switched, every road letter
Number receiving channel includes filter Filter and low-noise amplifier LNA, the LNA connection Filter;
First switching switchs the antenna for connecting the corresponding antenna sets of the receiving module, and second switching is opened
It closes for connecting emitting mould train and/or RF transceiver, and the receiving module is arranged close to the antenna sets, n1 is positive whole
Number, n2 are the integer more than or equal to 2.
Second aspect, the embodiment of the present application provide a kind of emitting mould train, including at least 1 road signal transmitting and receiving processing circuit and extremely
Few 1 channel selection switch, at least 1 road signal transmitting and receiving processing circuit connect at least one channel selection switch, each
Channel selection switch includes n1Pn2T switch, and includes the channel selecting for simplifying connection at least one channel selection switch
Switch, n1 are positive integer, and n2 is the integer more than or equal to 2.
The third aspect, the embodiment of the present application provide a kind of radio frequency system, including RF transceiver, rf processing circuitry and extremely
Few 2 antenna sets, the RF transceiver connect the rf processing circuitry, the rf processing circuitry connection described at least 2
A antenna sets;
Each antenna sets include 1 or 2 antennas, and at least two antenna sets include m branch antenna altogether, and m is more than or equal to 4
Less than or equal to 8, wherein the rf processing circuitry includes mould group identical with the group number quantity of at least two antenna sets, institute
Stating mould group includes emitting mould train or emitting mould train and receiving module, and each emitting mould train is close to each emitting mould train
The antenna sets connected, the antenna sets that each receiving module is connected close to each receiving module.
Fourth aspect, the embodiment of the present application provide a kind of electronic equipment, including radio frequency system, and the radio frequency system includes penetrating
Frequency transceiver, rf processing circuitry and at least two antenna sets, the RF transceiver connects the rf processing circuitry, described
Rf processing circuitry connects at least two antenna sets, and each antenna sets include 1 or 2 antennas, at least two antenna
Group includes m branch antenna altogether, and m is more than or equal to 4 and is less than or equal to 8;The rf processing circuitry includes and at least two antenna sets
The identical mould group of group number quantity, the mould group includes emitting mould train or emitting mould train and receiving module, and each transmitting mould
The antenna sets that group is connected close to each emitting mould train, each receiving module are connected close to each receiving module
Antenna sets;
The electronic equipment include at least it is following any one: mobile terminal, base station.
As can be seen that in the embodiment of the present application, since receiving module integrates at least 1 road signal receiving channel, and close to right
It answers antenna sets to be arranged, link Insertion Loss can be reduced, be conducive to promote channel sensitivity, be built compared to discrete device, integrated level is more
Height, area/cost/power consumption are more excellent.
Detailed description of the invention
In order to illustrate the technical solutions in the embodiments of the present application or in the prior art more clearly, to embodiment or will show below
There is attached drawing needed in technical description to be briefly described, it should be apparent that, the accompanying drawings in the following description is only this
Some embodiments of application for those of ordinary skill in the art without creative efforts, can be with
It obtains other drawings based on these drawings.
Figure 1A is a kind of structural schematic diagram of receiving module provided by the embodiments of the present application;
Figure 1B is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 C is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 D is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 E1 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 E2 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 F1 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 F2 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 G1 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 G2 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 H1 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 H2 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 I1 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 I2 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 J is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 K is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 L is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 M is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 N1 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 N2 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 O1 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 1 O2 is the structural schematic diagram of another receiving module provided by the embodiments of the present application;
Fig. 2A is a kind of structural schematic diagram of emitting mould train provided by the embodiments of the present application;
Fig. 2 B is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 2 C is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 2 D is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 2 E is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 2 F is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 2 G is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 2 H is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 2 I is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 2 J is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 2 K is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 2 L is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 2 M is the structural schematic diagram of another emitting mould train provided by the embodiments of the present application;
Fig. 3 is a kind of structural schematic diagram of radio frequency system provided by the embodiments of the present application;
Fig. 3 A is a kind of structural schematic diagram of radio frequency system provided by the embodiments of the present application;
Fig. 3 B is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 C is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 D is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 E is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 F is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 G is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 H is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 I is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 J is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 K is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 L is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 M is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 N is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 O is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 P is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 Q is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 R is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 S is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 T is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 U is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 V is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 W is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 X is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 Y is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 3 Z is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 A is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 B is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 C is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 D is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 E is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 F is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 G is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 H is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 I is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 J is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 K is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 L is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 M is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 N is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 O is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 P is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 Q is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 R is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 S is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 T is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 U is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 V is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 W is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 X is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application;
Fig. 4 Y is the structural schematic diagram of another radio frequency system provided by the embodiments of the present application.
Specific embodiment
Below in conjunction with the attached drawing in the embodiment of the present application, technical solutions in the embodiments of the present application carries out clear, complete
Site preparation description, it is clear that described embodiments are only a part of embodiments of the present application, instead of all the embodiments.It is based on
Embodiment in the application, those of ordinary skill in the art are obtained every other under that premise of not paying creative labor
Embodiment shall fall in the protection scope of this application.
The description and claims of this application and term " first " in above-mentioned attached drawing, " second " etc. are for distinguishing
Different objects, are not use to describe a particular order.In addition, term " includes " and " having " and their any deformations, it is intended that
It is to cover and non-exclusive includes.Such as the process, method, system, product or equipment for containing a series of steps or units do not have
It is defined in listed step or unit, but optionally further comprising the step of not listing or unit, or optionally also wrap
Include other step or units intrinsic for these process, methods, product or equipment.
Referenced herein " embodiment " is it is meant that a particular feature, structure, or characteristic described can wrap in conjunction with the embodiments
It is contained at least one embodiment of the application.Each position in the description occur the phrase might not each mean it is identical
Embodiment, nor the independent or alternative embodiment with other embodiments mutual exclusion.Those skilled in the art explicitly and
Implicitly understand, embodiment described herein can be combined with other embodiments.
Electronic equipment involved by the embodiment of the present application may include the various handheld devices with wireless communication function,
Mobile unit, wearable device calculate equipment or are connected to other processing equipments and various forms of radio modem
User equipment (User Equipment, UE), mobile station (Mobile Station, MS), terminal device (terminal
Device) etc..For convenience of description, apparatus mentioned above is referred to as electronic equipment.
Currently, the SRS switching switching4 antenna emission function of mobile phone is group, China Mobile CMCC in " China
Mobile 5G pilot test Technical White Paper for ××× _ terminal " in essential option, in third generation partner program 3GPP be it is optional,
Main purpose is in order to which base station is by measuring 4 antenna uplink signal of mobile phone, and then 4 path channels quality of confirmation and parameter, according to letter
Road reciprocity is directed to 4 path channels again and does the wave beam forming that downlink optimizes multiple-input and multiple-output Massive mimo antenna array,
Downlink 4x4MIMO is finally set to obtain optimum data transmission performance.
Wherein, the electronic equipment specifically can be 5G NR mobile phone terminal or other 5G NR terminal devices, such as client
Contract equipment (Customer Premise Equipment, CPE) or portable wideband wireless device (Mobile Wifi,
MIFI)。
The reason of defining receiving module and emitting mould train that the embodiment of the present application is presented is as follows, and 1. 5G NR needs downlink
4x4MIMO or 4 tunnel diversity receptions;2. TX SRS switching4 days line wheel sends out (optional);3. transmitting antenna handoff functionality (can
Choosing) 4. sub 6GHz band limits in 3.3~4.2G and 4.4~5G.Frequency range of this frequency range with respect to 600~2700MHz of LTE,
Frequency is higher.Therefore from mainboard side to the other side, and from mainboard to lower plate, RF cable is lost RF cable (coaxial line)
It is larger;
And system sensitivity formula Ps=10lg (KT)+10lg (BW)+NF+SNR,
K: Boltzmann constant (1.38 × E-23 unit: J/K)
T: 20 DEG C of room temperature, therefore T=293.15 are used in absolute temperature (273.15 units: K) formula
NF: noise coefficient Noise figure
BW: bandwidth
SNR: minimum demodulating thresholding is determined by platform supplier (high pass, MTK) Baseband algorithms.
In this formula, K, T are fixed constant, and BW is confirmed that SNR is determined by systems baseband algorithm by test bandwidth,
NF formula is as follows,
Wherein NF1=ILPre-1st LNA+NF1st LNAWherein ILPre-1st LNAFor the Insertion Loss before first order LNA, NF1st LNA
For the noise coefficient of the first order.This is the main contributions part of entire NF.
AndPart is contributed for rear class noise coefficient, in general, Gn > 15, NF2
~NFn < 5, this part are smaller to the contribution of NF.
In conclusion in radio-frequency front-end design, to promote sensitivity, it is necessary to reduce entire NF value.And NF1It is main again
Want contributor, NF1In, reduce NF in addition to using external LNA1st LNAOutside, how to reduce ILPre-1st LNABecome vital
How improvement means reduce the Insertion Loss before first order LNA.
In the embodiment of the present application, a kind of 5G NR receiving module and emitting mould train are defined, this mould group can be placed on day
Near line, to reach Insertion Loss before reducing first order LNA, improve the purpose of system sensitivity.
In a first aspect, the embodiment of the present application proposes a kind of receiving module, including at least 1 road signal receiving channel, first cut
Switch, the second switching switch are changed, the first switching switch connects at least 1 road signal receiving channel, at least 1 road letter
Number receiving channel connection the second switching switch, the first switching switch or the second switching switch are opened including n1Pn2T
It closes, every road signal receiving channel includes filter Filter and low-noise amplifier LNA, the LNA connection Filter;
First switching switchs the antenna for connecting the corresponding antenna sets of the receiving module, and second switching is opened
It closes for connecting emitting mould train and/or RF transceiver, and the receiving module is arranged close to the antenna sets, n1 is positive whole
Number, n2 are the integer more than or equal to 2.
As it can be seen that since receiving module integrates at least 1 road signal receiving channel, and being set close to respective antenna group in this example
It sets, link Insertion Loss can be reduced, be conducive to promote channel sensitivity, be built compared to discrete device, integrated level is higher, area/at
Sheet/power consumption is more excellent.
Wherein, 1 tunnel is additionally provided between the first switching switch and the second switching switch of the receiving module
Built in bypass channel, the built in bypass channel is for connecting emitting mould train to support the receiving module signal transmission function.
Wherein, the receiving module further includes 1 auxiliary port AUX, AUX connection the first switching switch, institute
Auxiliary port is stated for connecting emitting mould train to support the receiving module signal transmission function.Due to logical relative to external bypass
Road reduces a switch, so access Insertion Loss can be further decreased.
Wherein, the receiving module further includes 2 auxiliary port AUX, i.e. the first AUX and the 2nd AUX, the first AUX
Connection the first switching switch, the switching of the 2nd AUX connection second switch are arranged between the first AUX and the 2nd AUX
There is external bypass channel, the external bypass channel is used to connect emitting mould train to support the signal of the receiving module to emit function
Energy.
Wherein, the receiving module further includes 3 auxiliary port AUX, i.e. the first AUX, the 2nd AUX and the 3rd AUX, described
First AUX connects the first switching switch with the 2nd AUX, and the 3rd AUX connection second switching switchs, and described the
One AUX or the 2nd AUX is for connecting emitting mould train to support the signal transmission function for receiving mould group;Alternatively,
First AUX and the 3rd AUX or the 2nd AUX and the 3rd AUX is for accessing external bypass
Channel, the external bypass channel is for connecting emitting mould train to support the signal transmission function of the receiving module.
Wherein, the receiving module supports signal transmission function;
When the receiving module is set on the mainboard of electronic equipment, the connection of the receiving module first switching is opened
1 AUX closed is for connecting emitting mould train;Alternatively,
When the receiving module is set on the subplate of electronic equipment, the first AUX connect with the 3rd AUX or
2nd AUX is connect with the 3rd AUX.
As it can be seen that the receiving module can reduce the NF of receiving path, receiving sensitivity is promoted.
In addition, the receiving module further includes following characteristics:
(1) each receiving module is correspondingly connected with 1 antenna sets (including 1 or 2 antennas), and the company of being located proximate to is arranged
Antenna (feed point) position connect;
Optionally, (2) when multi signal receiving channel being needed to work at the same time, are somebody's turn to do for NR carrier wave polymerization CA scene of newly eating dishes without rice or wine
Receiving module can increase port number to access more cable lines, so that plurality of passages work at the same time, such mode is without increasing
Add device, but increase cable line, cost and module area more preferably control.Plurality of passages can be realized by increasing combiner
It works at the same time, such mode increases device, but without increasing cable line, cabling is more simplified.In addition, passing through 2 filters
Common port+special designing (i.e. composition duplexer or multiplexer), can complete combining behavior, such mode is without increasing
Cable line and device, cost and area more preferably control.
(3) this mould group carries shielded layer or without shielded layer (need to separately build shielding case when without shielded layer);
In addition, the receiving module further includes mobile industry processor interface MIPI and/or universal input/output GPIO control
Unit processed, the MIPI control unit and/or the GPIO control unit are used to control the device in the emitting mould train, institute
It states device to include any of the following: the first switching switch, the second switching switch.
Receiving module to support two-band dual band, not support uplink CA and downlink CA, connect single branch antenna below
For, the form for receiving module provided by the embodiment of the present application is described in detail.
As shown in Figure 1A, which includes 2 low-noise amplifier LNA, 2 filters, 2 switching switch (use
It is switched in the first switching switch of connection antenna and the second switching for connecting RF transceiver and/or emitting mould train, herein
Switched for 2 SP3T) and the built-in channel Bypass.Corresponding 2 frequency ranges of Nx and Ny.The receiving module can also include MIPI
And/or GPIO control unit completes LNA/ Switch Control.Wherein, the port P of the first switching switch (being switched including SP3T)
Antenna is connected, the first T-port of the first switching switch connects first filter, and first filter connects the first low noise amplification
Device LNA, the first T-port of the first low-noise amplifier LNA connection second switching switch (being switched including SP3T), first switching
Second T-port of switch connects second filter, and second filter connects the 2nd LNA, the 2nd LNA connection second switching switch
Second T-port, connection Bypass is logical between the third T-port of the first switching switch and the third T-port of the second switching switch
The port P in road, the second switching switch connects emitting mould train.
As shown in Figure 1B, which includes 2 low-noise amplifier LNA, 2 filters, and 2 switchings switch (the
One second switching switch is SP3T switch), 2 auxiliary port AUX (can be used for connecting the external channel Bypass, or connection
Emitting mould train completes SRS switch or autonomous handoff functionality).The receiving module can also include that MIPI and/or GPIO is controlled
Unit processed completes LNA/ Switch Control.Wherein, the connection relationship of internal components is similar with Figure 1A, and details are not described herein again.
As shown in Figure 1 C, which includes 2 low-noise amplifier LNA, 2 filters, and 2 switchings switch (the
One switching switch is that SP4T is switched, and the second switching switch is that SP3T is switched), 1 auxiliary port AUX and built-in Bypass it is logical
Road.The receiving module can also include that MIPI and/or GPIO control unit completes LNA/ Switch Control.Wherein, internal device
The connection relationship of part is similar with Figure 1A, and details are not described herein again.
As shown in figure iD, which includes 2 low-noise amplifier LNA, 2 filters, and 2 switchings switch (the
One switching switch is that SP4T is switched, and the second switching switch is that SP3T is switched), 3 auxiliary port AUX (AUX of connection SP3T switch
It can be used for connecting the external channel bypass Bypass with any one other AUX, the AUX of connection SP4T switch can be used for connecting transmitting
Mould group supports the emission function of respective antenna).The receiving module can also include that MIPI and/or GPIO control unit is completed
LNA/ Switch Control.Wherein, the connection relationship of internal components is similar with Figure 1A, and details are not described herein again.
Below for supporting two-band dual band, support 2 road CA of downlink and connect the receiving module of single branch antenna,
The form of receiving module provided by the embodiment of the present application is described in detail.
As shown in Fig. 1 E1, the receiving module includes 2 low-noise amplifier LNA, 2 filters, 2 combiners, 2
A switching switch, the built-in channel Bypass;Wherein, the port P of the first switching switch connects the antenna of corresponding antenna sets,
First T-port of the first switching switch connects the first combiner, and first combiner connects the first second filter,
The first filter connects the first LNA, and second filter connects the 2nd LNA, the one the second combining of LNA connection second
Device, second combiner connect first T-port of the second switching switch, second T of the first switching switch
The built-in channel Bypass is connected between port and second T-port of the second switching switch.
As shown in Fig. 1 E2, the receiving module includes 2 low-noise amplifier LNA, 2 filters, 2 combiners, 2
A switching switch, 2 auxiliary ports;Wherein, the port P of the first switching switch connects the antenna of corresponding antenna sets, institute
First T-port for stating the first switching switch connects the first combiner, and first combiner connects the first second filter,
The first filter connects the first LNA, and second filter connects the 2nd LNA, the one the second combining of LNA connection second
Device, second combiner connect first T-port of the second switching switch, second T of the first switching switch
Port connects the first AUX, and second T-port of the second switching switch connects the 2nd AUX, the first AUX and described the
Two AUX are for connecting the external channel Bypass, alternatively, the first AUX is for connecting emitting mould train to support respective antenna
Emission function.
As shown in Fig. 1 F1, which includes 2 low-noise amplifier LNA, duplexer (2 filters synthesis), and 1
A combiner, 2 switchings switch (the one the second switching switch be SPDT switch), the built-in channel Bypass.The receiving module
It can also include that MIPI and/or GPIO control unit completes LNA/ Switch Control.Wherein, the port P of the first switching switch
Connecting corresponding antenna, first T-port of the first switching switch connects duplexer, duplexer connection the one the second LNA, and first
2nd LNA connection combiner, first T-port of combiner connection the second switching switch, second end T of the first switching switch
The channel Bypass is set between mouth and second T-port of the second switching switch, and the port the P connection radio frequency that the second switching switchs is received
Send out device or emitting mould train.
As shown in Fig. 1 F2, which includes 2 low-noise amplifier LNA, and duplexer (is synthesized) by 2 filters,
1 combiner, 2 switchings switch (the one the second switching switch be SPDT switch) and 2 auxiliary port AUX (the one the second
Auxiliary port).The receiving module can also include that MIPI and/or GPIO control unit completes LNA/ Switch Control.Wherein,
The port P of first switching switch connects corresponding antenna, and first T-port of the first switching switch connects duplexer, duplexer
Connect the one the second LNA, the one the second LNA connection combiners, first T-port of combiner connection the second switching switch, institute
Second T-port for stating the first switching switch connects the first AUX, second T-port connection second of the second switching switch
AUX, the first AUX and the 2nd AUX are for connecting the external channel Bypass, alternatively, the first AUX is for connecting
Emitting mould train is to support the emission function of respective antenna.
As shown in Fig. 1 G1, which includes 2 low-noise amplifier LNA, 2 filters, 2 combiners, 2
It is (available to switch switches (the first switching switch is that SP3T is switched, and the second switching switch is SPDT switch), 1 auxiliary port
In connection emitting mould train, support the emission function of respective antenna), the built-in channel Bypass.The receiving module can also include
MIPI and/or GPIO control unit completes LNA/ Switch Control, and the auxiliary port is for connecting emitting mould train to support pair
The emission function of antenna is answered, the receiving module can not use the channel bypass at this time, due to reducing relative to the channel bypass
One switch, so can further decrease access Insertion Loss.Wherein, the connection relationship of internal components is similar with Fig. 1 F1, herein
It repeats no more.
As shown in Fig. 1 G2, which includes 2 low-noise amplifier LNA, 2 filters, 2 combiners, 2
Switch switches (the first switching switch is that SP3T is switched, and the second switching switch is SPDT switch), 3 auxiliary port AUX (the
2 T-ports of one the 2nd AUX connection first switching switch, the T-port of the 3rd AUX connection second switching switch).The reception mould
Group can also include that MIPI and/or GPIO control unit completes LNA/ Switch Control, the first AUX and the third
AUX or described 2nd AUX and the 3rd AUX are for connecting the external channel Bypass, alternatively, the first AUX or second
AUX is for connecting emitting mould train.The receiving module can not use the channel bypass at this time, due to subtracting relative to the channel bypass
Lack a switch, so access Insertion Loss can be further decreased.Wherein, the connection relationship of internal components is similar with Fig. 1 F1, this
Place repeats no more.
Below for supporting two-band dual band, support 2 road CA of downlink and connect the receiving module of 2 antennas,
Form for receiving module provided by the embodiment of the present application is described in detail.
As shown in Fig. 1 H1, which includes 2 low-noise amplifier LNA, 2 filters, 1 combiner, 2
Switching switch (the first switching switch is that DP3T is switched, and the second switching switch is SPDT switch), the built-in channel Bypass.The reception
Mould group can also include that MIPI and/or GPIO control unit completes LNA/ Switch Control.Wherein, the 2 of the first switching switch
A port P connects corresponding 2 antennas, and first T-port of the first switching switch connects first filter, and first filter connects
Meeting the first LNA, second T-port of the first switching switch connects second filter, and second filter connects the 2nd LNA, and first
2nd LNA connection combiner, first T-port of combiner connection the second switching switch, the end third T of the first switching switch
The channel Bypass is set between mouth and second T-port of the second switching switch, and the port the P connection radio frequency that the second switching switchs is received
Send out device or emitting mould train.
As shown in Fig. 1 H2, which includes 2 low-noise amplifier LNA, 2 filters, 1 combiner, 2
Switching switch (the first switching switch is that DP3T is switched, and the second switching switch is SPDT switch), 2 auxiliary port AUX (the one the
Two AUX, the T-port of the first AUX connection first switching switch, the T-port of the 2nd AUX connection second switching switch).The reception
Mould group can also include that MIPI and/or GPIO control unit completes LNA/ Switch Control.Wherein, the 2 of the first switching switch
A port P connects corresponding 2 antennas, and first T-port of the first switching switch connects first filter, and first filter connects
Meeting the first LNA, second T-port of the first switching switch connects second filter, and second filter connects the 2nd LNA, and first
2nd LNA connection combiner, first T-port of combiner connection the second switching switch, the first AUX and described second
AUX is for connecting the external channel Bypass, alternatively, the first AUX is for connecting emitting mould train to support the hair of respective antenna
Penetrate function.
As shown in Fig. 1 I1, which includes 2 low-noise amplifier LNA, 2 filters, 1 combiner, 2
Switching switch (the first switching switch is that DP4T is switched, and the second switching switch is SPDT switch), 1 auxiliary port AUX (can be used for
Connect emitting mould train transmitting SRS TX port), the built-in channel Bypass.The receiving module can also include MIPI and/or
GPIO control unit completes LNA/ Switch Control.Wherein, the connection relationship of internal components is similar with Fig. 1 H1, herein no longer
It repeats.
As shown in Fig. 1 I2, which includes 2 low-noise amplifier LNA, 2 filters, 1 combiner, 2
Switching switch (the first switching switch is that DP4T is switched, and the second switching switch is SPDT switch), 3 auxiliary port AUX (the one the
Two AUX connections first switching switch 2 T-ports, the 3rd AUX connection second switching switch T-port), the first AUX with
3rd AUX or described, 2nd AUX and the 3rd AUX is for connecting the external channel Bypass, alternatively, the first AUX
Or the 2nd AUX for connecting emitting mould train.The receiving module can also include that MIPI and/or GPIO control unit completes LNA/
Switch Control.Wherein, the connection relationship of internal components is similar with Fig. 1 H1, and details are not described herein again.
As shown in figure iJ, which includes 2 low-noise amplifier LNA, 2 filters, and 2 switchings switch (the
One second switching switch be DP3T switch), the built-in channel Bypass.The receiving module can also include MIPI and/or GPIO
Control unit completes LNA/ Switch Control.Wherein, 2 ports P of the first switching switch connect corresponding 2 antennas, the
First T-port of one switching switch connects first filter, and first filter connects the first LNA, and the first LNA connection second is cut
Change first T-port of switch, second T-port of the first switching switch connects second filter, second filter connection the
The third T-port and second of two LNA, second T-port of the 2nd LNA connection second switching switch, the first switching switch are cut
Change between the third T-port of switch the setting channel Bypass, 2 ports P connection emitting mould train of the second switching switch and/
Or RF transceiver.
As shown in figure iK, the receiving module includes 2 low-noise amplifier LNA, 2 filters, 2 switching switches, 1
A auxiliary port AUX, the built-in channel Bypass, it is described 2 switching switch in first switching switch be DP4T switch, second
Switching switch is that DP3T is switched, and the auxiliary port connects for connecting emitting mould train, the first T-port of the first switching switch
First filter is connect, the first filter connects the first LNA, and the first LNA connects the first T of the second switching switch
Port, the second T-port of the first switching switch connect second filter, and the second filter connects the 2nd LNA, described
2nd LNA connects the second T-port of the second switching switch, and the third T-port of the first switching switch connects the AUX.
As can be seen in 1L, the receiving module includes 2 low-noise amplifier LNA, 2 filters, 2 switching switches, 3
A auxiliary port AUX, it is that DP4T is switched that described 2, which switch the first switching switch opened, and the second switching switch is that DP3T is switched,
Second T-port of first cut-flower switch connects first filter, and the first filter connects the first LNA, and described first
The third T-port of first port T of the switching switch of LNA connection second, the first cut-flower switch connects second filter, institute
It states second filter and connects the 2nd LNA, the second T-port of the switching of the 2nd LNA connection second switch, the first switching switch
The first T-port and the 4th T-port be separately connected the first AUX and the 2nd AUX, the third T-port of the second switching switch
It is external for connecting to connect the 3rd AUX, the first AUX and 2nd AUX of the 3rd AUX or described and the 3rd AUX
The channel Bypass, the first AUX or the 2nd AUX is for connecting emitting mould train.
As depicted in figure iM, the receiving module includes 2 low-noise amplifier LNA, 2 filters, 2 switching switches, 2
A auxiliary port AUX, the first T-port of the first switching switch connect first filter, the first filter connection first
LNA, the first T-port of the switching of the first LNA connection second switch, the second filter of the second T-port connection of the first switching switch
Wave device, the second filter connect the 2nd LNA, the second T-port that the switching of the 2nd LNA connection second switchs, and described the
The third T-port of one switching switch connects the first AUX, and the third T-port of the second switching switch connects the 2nd AUX, described
First switching switch and the second switching switch are DP3T switch, the first AUX and the 2nd AUX outer for connecting
The channel Bypass is set, alternatively, the first AUX is for connecting emitting mould train to support the emission function of respective antenna.
As shown in Fig. 1 N1, which includes 1 low-noise amplifier LNA, 1 filter, and 2 switchings switch (the
One switching switch be SPDT switch, second switching switch be SPDT switch), built in bypass channel.Wherein, the connection of internal components
Relationship is similar with Fig. 1 K, and details are not described herein again.
As shown in Fig. 1 N2, which includes 1 low-noise amplifier LNA, 1 filter, and 2 switchings switch (the
One switching switch is SPDT switch, and the second switching switch is SPDT switch), 2 auxiliary port AUX (can be used for connecting external
The channel Bypass, or the port of the transmitting SRS for connecting emitting mould train).Wherein, the connection relationship of internal components and Fig. 1 K
Similar, details are not described herein again.
As shown in Fig. 1 O1, the receiving module include 1 low-noise amplifier LNA, 1 filter, 2 switchings switch,
1 auxiliary port AUX and built in bypass channel, the first T-port of the first switching switch connect the first AUX, the first switching switch
The second T-port connect filter, the filter connects LNA, the first T-port that the switching of LNA connection second switchs, institute
The third T-port for stating the first switching switch connects the 2nd AUX, and the second T-port of the second switching switch connects the 3rd AUX;
The first switching switch is that SP3T is switched, and the second switching switch is SPDT switch, and AUX is for connecting emitting mould train to prop up
The emission function of respective antenna is held, built in bypass channel is for connecting emitting mould train to support the emission function of respective antenna.
As shown in Fig. 1 O2, the receiving module include 1 low-noise amplifier LNA, 1 filter, 2 switchings switch,
3 auxiliary port AUX, the first T-port of the first switching switch connect the first AUX, the second T-port connection of the first switching switch
Filter, the filter connect LNA, the first T-port of the switching of LNA connection second switch, the first switching switch
Third T-port connect the 2nd AUX, it is described second switching switch the second T-port connect the 3rd AUX;First switching is opened
Closing is that SP3T is switched, and the second switching switch is SPDT switch;First AUX and the 3rd AUX or described second
AUX and the 3rd AUX is for connecting the external channel Bypass or the first AUX or the 2nd AUX for connecting transmitting
Mould group.
As can be seen that in the embodiment of the present application, since receiving module can be supported by bypass channel or auxiliary port
The handoff functionality of transmitting antenna, and each mould group is arranged close to respective antenna group, is conducive to promote each channel sensitivity, compares and divides
It is built from device, integrated level is higher, and area/cost/power consumption is more excellent.
Second aspect, the embodiment of the present application propose a kind of emitting mould train, including at least 1 road signal transmitting and receiving processing circuit and extremely
Few 1 channel selection switch, at least 1 road signal transmitting and receiving processing circuit connect at least one channel selection switch, each
Channel selection switch is n1Pn2T switch, and includes full connection or simplified connection at least one channel selection switch
Channel selection switch, n1 are positive integer, and n2 is the integer more than or equal to 2.
At least one channel selection switch connects antenna sets corresponding to the emitting mould train, and the emitting mould train
It is arranged close to the antenna sets.
Wherein, the channel selection switch of the simplified connection refers to that the channel including one or more non-full connectivity ports is selected
Switch is selected, the non-full connectivity port refers to the port for being not connected with all Peer-Ports, in 4P4T switch, first T-port
4 ports P can be connected entirely, and each T-port can only connect 1 port P in the second the 3rd the 4th T-port.
As it can be seen that since emitting mould train integrates at least 1 road signal transmitting and receiving processing circuit, and including simplified connection in this example
Channel selection switch, can reduce radio frequency link number of switches, reduce link Insertion Loss, be conducive to promote each channel sensitivity,
It is built compared to discrete device, integrated level is higher, and area/cost/power consumption is more excellent.
The first kind:
The emitting mould train supports 1 frequency range, the emitting mould train to support 1 frequency range, and the emitting mould train further includes 1
Power coupler, the signal transmitting and receiving processing circuit include 1 power amplifier PA, 1 low-noise filter LNA, 1 transmitting-receiving
Switching switch, 1 filter Filter, the PA and the LNA connect the transceiver toggle switch, the transceiver toggle switch
The Filter is connected, the signal transmitting and receiving processing circuit connects the power coupler and at least one channel selecting is opened
It closes, the transceiver toggle switch includes SPDT switch.
Wherein, the quantity of at least one channel selection switch be 1, the channel selection switch be 4P4T switch or
DP3T switch, the Filter connection power coupler, the power coupler connect the channel selection switch.
Wherein, the quantity of at least one channel selection switch is 2, and at least one channel selection switch includes first
Channel selection switch and second channel selection switch, the first passage selection switch includes SPDT switch, the second channel
Selection switch includes that 4P4T is switched, and the Filter connection of the signal transmitting and receiving processing circuit first passage selection is opened
It closes, the first passage selection switch connects the power coupler, and the power coupler connects the second channel selection
Switch;
The remaining T-port of first passage selection switch corresponds to the auxiliary port AUX of the emitting mould train, described
AUX is used to access the emitting mould train of other frequency ranges, and the remaining T-port is the T-port for being not connected with the Filter.
Wherein, the emitting mould train further includes 1 road signal receiving channel, and the signal receiving channel includes 1 Filter
With 1 LNA, LNA connection Filter, Filter connection at least one channel selection switch.
Wherein, the emitting mould train further includes 1 power detection selection switch, and the power coupler connects the power
Detect and select switch.
Wherein, the input port of the PA of the signal transmitting and receiving processing circuit is used to connect the signal hair of RF transceiver
Port is penetrated, the signal that the output port of the LNA of the signal transmitting and receiving processing circuit is used to connect the RF transceiver connects
Receiving end mouth, the power coupler are used to connect the port power detection PDET of the RF transceiver, alternatively, the power is examined
The port P for surveying selection switch is used to connect the port PDET of the RF transceiver;
The output port of the LNA of the signal receiving channel is used to connect the signal receiving end of the RF transceiver
Mouthful.
Wherein, external-connected port of at least three port as the emitting mould train at least one channel selection switch,
Wherein 1 or 2 external-connected ports are used to connect the antenna of antenna sets, and remaining external-connected port is for connecting receiving module and/or institute
State RF transceiver and/or the receiver port of other emitting mould trains.
Second class:
The emitting mould train supports n frequency range, and n is 2 or 3, and the emitting mould train further includes 1 power coupler, described
At least 1 road signal transmitting and receiving processing circuit is the road n, and every road signal transmitting and receiving processing circuit includes 1 PA, 1 LNA, 1 transmitting-receiving switching
Switch, 1 Filter, the PA connects transceiver toggle switch with the LNA, described in the transceiver toggle switch connects
Filter, the road the n signal transmitting and receiving processing circuit connect the power coupler and at least one channel selection switch, institute
Stating transceiver toggle switch includes SPDT switch.
Wherein, the quantity of at least one channel selection switch is 2, including first passage selection switch and second channel
Selection switch, the first passage selection switch include SPnT switch or SP (n+1) T switch, SP (n+1) the T switch
Remaining 1 T-port includes that 4P4T is switched for accessing other emitting mould trains, the second channel selection switch, the signal
The selection switch of first passage described in transmitting-receiving process circuit connection, the first passage selection switch connect the power coupler,
The power coupler connects the second channel selection switch;
Alternatively, the first passage selection switch includes that 3P3T is switched, the second channel selection switch is opened including 3P3T
It closes.
Wherein, which further includes 1 power detection selection switch, and power coupler is also connected with power detection selection
Switch.
Wherein, the input port of the PA of the signal transmitting and receiving processing circuit is used to connect the signal hair of RF transceiver
Port is penetrated, the signal that the output port of the LNA of the signal transmitting and receiving processing circuit is used to connect the RF transceiver connects
Receiving end mouth, the power coupler are used to connect the port power detection PDET of the RF transceiver, alternatively, the power is examined
The port P for surveying selection switch is used to connect the port PDET of the RF transceiver;
The output port of the LNA of the signal receiving channel is used to connect the signal receiving end of the RF transceiver
Mouthful.
Wherein, external-connected port of at least three port as the emitting mould train at least one channel selection switch,
Wherein 1 or 2 external-connected ports are used to connect the antenna of antenna sets, and remaining external-connected port is for connecting receiving module and/or institute
State RF transceiver and/or the receiver port of other emitting mould trains.
Third class:
The quantity for the frequency range that the emitting mould train is supported is 2 or 3, then emitting mould train includes the road n signal transmitting and receiving processing circuit, function
Rate detects and selects switch, multiple channel selection switches, and every road signal transmitting and receiving processing circuit includes 1 PA, 1 LNA, 1 transmitting-receiving
Switching switch (including SPDT switch), 1 Filter, 1 power coupler, PA connect transceiver toggle switch with LNA, receive and dispatch
Switching switch connection Filter, Filter connection power coupler, the road n signal transmitting and receiving processing circuit connect multiple channel selectings and open
It closes and power detection selection switchs, power detection selection switch includes that SPnT switch or SP (n+1) T are switched, wherein the SP
(n+1) remaining T-port is used to merge the power detection channels of other emitting mould trains, the transceiver toggle switch packet in T switch
SPDT switch is included, the remaining T-port is the port T for being not connected with the road the n signal transmitting and receiving processing circuit.
Wherein, multiple channel selection switches are 2, and first passage selection switch includes that SPnT switch or SP (n+1) T are opened
It closes, (under SP (n+1) T switch conditions, remaining 1 T-port is used for: accessing other emitting mould trains), second channel selection switch
It is switched including 4P4T;Alternatively, the first second channel selection switch includes that 3P3T is switched, signal transmitting and receiving processing circuit connection first is logical
Road selection switch, first passage selection switch connection second channel selection switch.
Wherein, multiple channel selection switches are 3, and first passage selection switch includes that 3P3T is switched, second channel selection
Switch includes that SP3T is switched, and third channel selection switch includes that SP4T is switched, and signal transmitting and receiving processing circuit connects first passage choosing
Select switch, first passage selection switch connection second channel selection switch and third channel selection switch.
Wherein, the input port of the PA of the signal transmitting and receiving processing circuit is used to connect the signal hair of RF transceiver
Port is penetrated, the signal that the output port of the LNA of the signal transmitting and receiving processing circuit is used to connect the RF transceiver connects
Receiving end mouth, the power coupler are used to connect the port power detection PDET of the RF transceiver, alternatively, the power is examined
The port P for surveying selection switch is used to connect the port PDET of the RF transceiver;
The output port of the LNA of the signal receiving channel is used to connect the signal receiving end of the RF transceiver
Mouthful.Power detection selection switchs remaining T-port and is used for: if there is the individual module of other frequency ranges, the power of the individual module
Detection can be tapped into this mouth finally to return to the port power detection PDET of RF transceiver by the port P.
Wherein, external-connected port of at least three port as the emitting mould train at least one channel selection switch,
Wherein 1 or 2 external-connected ports are used to connect the antenna of antenna sets, and remaining external-connected port is for connecting receiving module and/or institute
State RF transceiver and/or the receiver port of other emitting mould trains.
Wherein, the emitting mould train even further includes mobile industry processor interface MIPI and/or universal input/output GPIO
Control unit, the MIPI control unit and/or the GPIO control unit are used to control the device in the emitting mould train,
The device includes any of the following: transceiver toggle switch, channel selection switch, power detection selection switch.
It is illustrated below with reference to specific example.
As shown in Figure 2 A, which includes 2 road signal transmitting and receiving processing circuits, 1 power coupler and 2 channel choosings
Switch (including first passage selection switch and second channel selection switch) is selected, every road signal transmitting and receiving processing circuit includes 1 function
Rate amplifier PA, 1 low-noise amplifier LNA, 1 transceiver toggle switch (including SPDT switch), 1 filter, PA and LNA
Transceiver toggle switch is connected, transceiver toggle switch connects filter, and signal transmitting and receiving processing circuit connects first passage selection switch,
First passage selection switch connection power coupler, power coupler connect second channel selection switch
The emitting mould train even can also include that MIPI and/or GPIO control unit completes PA/LNA/ power coupler
Coupler/ Switch Control.
Wherein, the first PA and the first LNA the first transceiver toggle switch of connection, the first filtering of the first transceiver toggle switch connection
Device, the 2nd PA and the 2nd LNA the second transceiver toggle switch of connection, the second transceiver toggle switch connect second filter, and the one the
Two filters connect 2 T-ports of first passage selection switch (including SPDT switch), the port P of first passage selection switch
The first port of power coupler is connected, (including 4P4T is opened the second port connection second channel selection switch of power coupler
Close) first T-port;
The input port of first PA corresponds to the first external-connected port of emitting mould train, the corresponding transmitting of the output port of the first LNA
Second external-connected port of mould group, the input port of the 2nd PA correspond to the third external-connected port of emitting mould train, the output end of the 2nd LNA
First port P of the 4th external-connected port of the corresponding emitting mould train of mouth, second channel selection switch corresponds to the 5th of emitting mould train
Second port P of external-connected port, second channel selection switch corresponds to the 6th external-connected port of emitting mould train, second channel selection
The port third P of switch corresponds to the 7th external-connected port of emitting mould train, and the 4th port P of second channel selection switch is corresponding
8th external-connected port of emitting mould train, the third port of power coupler correspond to the 9th external-connected port of emitting mould train, and second is logical
Second T-port of road selection switch corresponds to the tenth external-connected port of emitting mould train, the third T of second channel selection switch
Port corresponds to the 11st external-connected port of emitting mould train, and the 4th T-port of second channel selection switch corresponds to emitting mould train
12nd external-connected port.
Wherein, first, third external-connected port is used to connect the signal emission port of RF transceiver, and the 5th external-connected port is used
In the antenna for connecting corresponding antenna sets, the six, the seven, the 8th external-connected ports are for connecting receiving module or for connecing
Receive mould group and emitting mould train, the 9th external-connected port is used to connect the port power detection PDET of RF transceiver, second, the 4th,
Ten, the 11st, the external-connected port in the 12nd external-connected port is used to connect the receiver port of RF transceiver, alternatively,
Ten, the 11st, the external-connected port in the 12nd external-connected port is used to connect the external-connected port of other emitting mould trains.
As shown in Figure 2 B, which includes 3 road signal transmitting and receiving processing circuits, 1 power coupler and 2 channel choosings
Select switch, every road signal transmitting and receiving processing circuit include 1 power amplifier PA, 1 LNA, 1 transceiver toggle switch (including
SPDT switch), 1 Filter.The emitting mould train even can also include that MIPI and/or GPIO control unit completes PA/LNA/ function
Rate coupler Coupler/ Switch Control.
Wherein, the first PA and the first first the first transceiver toggle switch of LNA connection, the first transceiver toggle switch connection the
One filter, the 2nd PA and the 2nd LNA the second transceiver toggle switch of connection, the second transceiver toggle switch connect second filter,
3rd PA and the 3rd LNA connection third transceiver toggle switch, third transceiver toggle switch connect third filter, and the one the second the
Three filters connect 3 T-ports of first passage selection switch (including SP3T), the port the P connection of first passage selection switch
Power coupler, the second port of power coupler connect first end T of 1 second channel selection switch (including 4P4T)
Mouthful;
The input port of first PA corresponds to the first external-connected port of emitting mould train, the corresponding transmitting of the output port of the first LNA
Second external-connected port of mould group, the input port of the 2nd PA correspond to the third external-connected port of emitting mould train, the output end of the 2nd LNA
4th external-connected port of the corresponding emitting mould train of mouth, the input port of the 3rd PA correspond to the 5th external-connected port of emitting mould train, third
The output port of LNA corresponds to the 6th external-connected port of emitting mould train, the corresponding transmitting in first port P of second channel selection switch
Second port P of the 7th external-connected port of mould group, second channel selection switch corresponds to the 8th external-connected port of emitting mould train, the
The port third P of two channel selection switches corresponds to the 9th external-connected port of emitting mould train, and second channel selects the 4th of switch
A port P corresponds to the tenth external-connected port of emitting mould train, and the third port of power coupler corresponds to outside the 11st of emitting mould train
Port is connect, second T-port of second channel selection switch corresponds to the 12nd external-connected port of emitting mould train, second channel selection
The third T-port of switch corresponds to the 13rd external-connected port of emitting mould train, the 4th T-port pair of second channel selection switch
Answer the 14th external-connected port of emitting mould train.
Wherein, first, third, the 5th external-connected port are used to connect the signal emission port of RF transceiver, and the 7th is external
Port is used to connect the antenna of corresponding antenna sets, and the eight, the nine, the tenth external-connected ports are for connecting receiving module or being used for
Receiving module and emitting mould train are connected, the 11st external-connected port is used to connect the port power detection PDET of RF transceiver, the
Two, the four, the six, the 12nd, the 13rd, the external-connected port in the 14th external-connected port is used to connect the signal of RF transceiver
Receiving port, alternatively, the six, the 12nd, the 13rd, the external-connected port in the 14th external-connected port is for connecting other transmitting moulds
The external-connected port of group.
As shown in Figure 2 C, which includes 1 road receiving and transmitting signal processing circuit, 1 power coupler and 1 channel choosing
Switch is selected, receiving and transmitting signal processing circuit includes PA, 1 LNA, 1 transceiver toggle switch (including SPDT switch), 1 filter.
The emitting mould train even can also include that MIPI and/or GPIO control unit completes PA/LNA/ power coupler Coupler/ switch
Switching control.Wherein, the connection relationship of internal components is similar with Fig. 2A, 2B, and details are not described herein again.
As shown in Figure 2 D, which includes 1 road receiving and transmitting signal processing circuit, 1 power coupler and 2 channel choosings
Switch is selected, receiving and transmitting signal processing circuit includes 1 PA, 1 LNA, 1 transceiver toggle switch (including SPDT switch), 1 filtering
Device, wherein first passage selects switch for SPDT switch, and the remaining T-port of the switch is used to access the transmitting mould of other frequency ranges
Group.The emitting mould train even can also include that MIPI and/or GPIO control unit completes PA/LNA/ power coupler Coupler/
Switch Control.Wherein, the connection relationship of internal components is similar with Fig. 2A, 2B, and details are not described herein again.
As shown in Figure 2 E, which includes 2 road signal transmitting and receiving processing circuits, 2 channel selection switches and 1 power
Detect and select switch.The emitting mould train even can also include that MIPI and/or GPIO control unit completes PA/LNA/ power coupler
Coupler/ Switch Control.
First PA and the first LNA the first transceiver toggle switch of connection (including SPDT switch), the first transceiver toggle switch connect
First filter is connect, first filter connects the first power coupler, the 2nd PA and the 2nd LNA the second transceiver toggle switch of connection
(including SPDT switch), the second transceiver toggle switch connect second filter, and second filter connects the second power coupler, the
One second power coupler connects power detection selection switch (including SPDT switch), the one the second power coupler connections first
Channel selection switch (including SPDT switch), first passage selection switch connection second channel selection switch (including 4P4T is opened
It closes).
The input port of first PA corresponds to the first external-connected port of emitting mould train, the corresponding transmitting of the output port of the first LNA
Second external-connected port of mould group, the input port of the 2nd PA correspond to the third external-connected port of emitting mould train, the output end of the 2nd LNA
First port P of the 4th external-connected port of the corresponding emitting mould train of mouth, second channel selection switch corresponds to the 5th of emitting mould train
Second port P of external-connected port, second channel selection switch corresponds to the 6th external-connected port of emitting mould train, second channel selection
The port third P of switch corresponds to the 7th external-connected port of emitting mould train, and the 4th port P of second channel selection switch is corresponding
8th external-connected port of emitting mould train, the port P of power detection selection switch correspond to the 9th external-connected port of emitting mould train, and second
3 T-ports of residue (T-port of not connected the one the second power coupler) of channel selection switch respectively correspond emitting mould train
Ten, the 11st, the 12nd external-connected port.
Wherein, first, third external-connected port is used to connect the signal emission port of RF transceiver, and the five, the 6th is external
Port is used to connect the antenna of corresponding antenna sets, and the seven, the eight, the 9th external-connected ports are for connecting receiving module or being used for
Connecting receiving module and emitting mould train, the tenth external-connected port is used to connect the port power detection PDET of RF transceiver, and the tenth
One external-connected port for the optional power detection channel for connecting other mould groups to realize power detection, second, the four, the 12nd,
13rd, the 14th, receiver port of the external-connected port in the 15th external-connected port for optional connection RF transceiver,
Alternatively, the 12nd, the 13rd, the 14th, the external-connected port in the 15th external-connected port be used to connect the outer of other emitting mould trains
Connect port.
As shown in Figure 2 F, which includes 2 road signal transmitting and receiving processing circuits, 2 channel selection switches (including SPDT
Switch and 4P4T switch) and 1 power detection selection switch, signal transmitting and receiving processing circuit include 1 PA, 1 LNA, 1 receive
Hair switching switch (including SPDT switch), 1 filter, 1 power coupler.The emitting mould train even can also include MIPI
And/or GPIO control unit completes PA/LNA/ power coupler Coupler/ Switch Control.Wherein, the company of internal components
It is similar with Fig. 2 E to connect relationship, details are not described herein again.
As shown in Figure 2 G, which includes 2 road signal transmitting and receiving processing circuits, 2 channel selection switches (including 3P3T
Switch) and 1 power detection selection switch, signal transmitting and receiving processing circuit includes 1 PA, 1 LNA, 1 transceiver toggle switch
(including SPDT switch), 1 filter, 1 power coupler.The emitting mould train even can also include that MIPI and/or GPIO is controlled
Unit processed completes PA/LNA/ power coupler Coupler/ Switch Control.Wherein,
First PA and the first LNA the first transceiver toggle switch of connection, the first transceiver toggle switch connect first filter, the
One filter connects the first power coupler, the 2nd PA and the 2nd LNA the second transceiver toggle switch of connection, and the second transmitting-receiving switching connects
Connect second filter, second filter connects the second power coupler, the one the second power coupler connection power detection selections
Switch (including SP3T switch, wherein 1 external-connected port of remaining 1 port T as emitting mould train, the external-connected port are used for
N power coupler access of other emitting mould trains is switched to the output of power coupling path), the one the second power couplings
Device is also connected with the switch set including 2 channel selection switches, and first passage selection switch is opened including 3P3T in the switch set
It closes, second channel selection switch includes that 3P4T is switched, first passage selection switch connection second channel selection switch.
The input port of first PA corresponds to the first external-connected port of emitting mould train, the corresponding transmitting of the output port of the first LNA
Second external-connected port of mould group, the input port of the 2nd PA correspond to the third external-connected port of emitting mould train, the output end of the 2nd LNA
First port P of the 4th external-connected port of the corresponding emitting mould train of mouth, first passage selection switch corresponds to the 5th of emitting mould train
Second port P of external-connected port, first passage selection switch corresponds to the 6th external-connected port of emitting mould train, second channel selection
First port P of switch corresponds to the 7th external-connected port of emitting mould train, and second port P of second channel selection switch is corresponding
The port third P of 8th external-connected port of emitting mould train, second channel selection switch corresponds to the 9th external connection end of emitting mould train
Mouthful, the port P of power detection selection switch corresponds to the tenth external-connected port of emitting mould train, the remaining T of power detection selection switch
11st external-connected port of the corresponding emitting mould train in port (not with the T-port of the one the second power coupler connections), first passage
Select the 12nd external of remaining T-port (T-port of not connected the one the second power coupler) corresponding emitting mould train of switch
Port, 3 T-ports of residue (T-port of not connected third channel selection switch) corresponding transmitting mould of second channel selection switch
The external-connected port of the 13rd, 14 and 15 of group.
Wherein, first, third external-connected port is used to connect the signal emission port of RF transceiver, and the five, the 6th is external
Port is used to connect the antenna of corresponding antenna sets, and the seven, the eight, the 9th external-connected ports are for connecting receiving module or being used for
Connecting receiving module and emitting mould train, the tenth external-connected port is used to connect the port power detection PDET of RF transceiver, and the tenth
One external-connected port for the optional power detection channel for connecting other mould groups to realize power detection, second, the four, the 12nd,
13rd, the 14th, the external-connected port in the 15th external-connected port be used to connect the receiver port of RF transceiver, or
Person, the 12nd, the 13rd, the 14th, the external-connected port in the 15th external-connected port is for connecting the external of other emitting mould trains
Port.
As illustrated in figure 2h, which includes 2 road signal transmitting and receiving processing circuits, 3 channel selection switches (including 3P3T
Switch, SP3T switch and SP4T switch) and 1 power detection selection switch, signal transmitting and receiving processing circuit includes 1 PA, 1
LNA, 1 transceiver toggle switch (including SPDT switch), 1 filter, 1 power coupler.The emitting mould train even can be with
PA/LNA/ power coupler Coupler/ Switch Control is completed including MIPI and/or GPIO control unit.Wherein,
First PA and the first LNA the first transceiver toggle switch of connection, the first transceiver toggle switch connect first filter, the
One filter connects the first power coupler, the 2nd PA and the 2nd LNA the second transceiver toggle switch of connection, and the second transmitting-receiving switching is opened
Connection connects second filter, and second filter connects the second power coupler, and the one the second power couplers connect power detection
Selection switch (including SP3T switch, wherein 1 external-connected port of remaining 1 T-port as emitting mould train, the external-connected port
For n power coupler access of other emitting mould trains to be switched to the output of power coupling path), the one the second power
Coupler is also connected with the switch set including 3 channel selection switches, and first passage selection switch includes in the switch set
3P3T switch, second channel selection switch include that SP3T is switched, and third channel selection switch includes that SP4T is switched, first passage choosing
Select switch connection the second third channel selection switch.
The input port of first PA corresponds to the first external-connected port of emitting mould train, the corresponding transmitting of the output port of the first LNA
Second external-connected port of mould group, the input port of the 2nd PA correspond to the third external-connected port of emitting mould train, the output end of the 2nd LNA
First port P of the 4th external-connected port of the corresponding emitting mould train of mouth, first passage selection switch corresponds to the 5th of emitting mould train
Second port P of external-connected port, first passage selection switch corresponds to the 6th external-connected port of emitting mould train, second channel selection
First port P of switch corresponds to the 7th external-connected port of emitting mould train, and second port P of second channel selection switch is corresponding
The port third P of 8th external-connected port of emitting mould train, second channel selection switch corresponds to the 9th external connection end of emitting mould train
Mouthful, the port P of power detection selection switch corresponds to the tenth external-connected port of emitting mould train, the remaining T of power detection selection switch
11st external-connected port of port (T-port of not connected the one the second power coupler) corresponding emitting mould train, third channel choosing
The the one the second the 3rd the 4th T-ports for selecting switch correspond to the external-connected port of the 12nd, 13,14 and 15 of emitting mould train.
Wherein, first, third external-connected port is used to connect the signal emission port of RF transceiver, and the five, the 6th is external
Port is used to connect the antenna of corresponding antenna sets, and the seven, the eight, the 9th external-connected ports are for connecting receiving module or being used for
Connecting receiving module and emitting mould train, the tenth external-connected port is used to connect the port power detection PDET of RF transceiver, and the tenth
One external-connected port for the optional power detection channel for connecting other mould groups to realize power detection, second, the four, the 12nd,
13rd, the 14th, the external-connected port in the 15th external-connected port be used to connect the receiver port of RF transceiver, or
Person, the 12nd, the 13rd, the 14th, the external-connected port in the 15th external-connected port is for connecting the external of other emitting mould trains
Port.
As shown in figure 2i, which includes 2 road signal transmitting and receiving processing circuits, 2 channel selection switches (including 3P3T
Switch) and 1 power detection selection switch, signal transmitting and receiving processing circuit includes 1 PA, 1 LNA, 1 transceiver toggle switch
(including SPDT switch), 1 filter, 1 power coupler.The emitting mould train even can also include that MIPI and/or GPIO is controlled
Unit processed completes PA/LNA/ power coupler Coupler/ Switch Control.Wherein,
First PA and the first LNA the first transceiver toggle switch of connection, the first transceiver toggle switch connect first filter, the
One filter connects the first power coupler, the 2nd PA and the 2nd LNA the second transceiver toggle switch of connection, and the second transmitting-receiving switching is opened
Connection connects second filter, and second filter connects the second power coupler, and the one the second power couplers connect power detection
Selection switch (including SP3T switch, wherein 1 external-connected port of remaining 1 T-port as emitting mould train, the external-connected port
For n power coupler access of other emitting mould trains to be switched to the output of power coupling path), the one the second power
Coupler is also connected with 2 channel selection switches, and the first second channel selection switch includes that 3P3T is switched, and first passage selection is opened
Connection connects second channel selection switch.
The input port of first PA corresponds to the first external-connected port of emitting mould train, the corresponding transmitting of the output port of the first LNA
Second external-connected port of mould group, the input port of the 2nd PA correspond to the third external-connected port of emitting mould train, the output end of the 2nd LNA
First port P of the 4th external-connected port of the corresponding emitting mould train of mouth, first passage selection switch corresponds to the 5th of emitting mould train
Second port P of external-connected port, first passage selection switch corresponds to the 6th external-connected port of emitting mould train, second channel selection
First port P of switch corresponds to the 7th external-connected port of emitting mould train, and second port P of second channel selection switch is corresponding
The port third P of 8th external-connected port of emitting mould train, second channel selection switch corresponds to the 9th external connection end of emitting mould train
Mouthful, the port P of power detection selection switch corresponds to the tenth external-connected port of emitting mould train, the remaining T of power detection selection switch
11st external-connected port of port (T-port of not connected the one the second power coupler) corresponding emitting mould train, first passage choosing
The third T-port for selecting switch corresponds to the 12nd external-connected port of emitting mould train, the second third T-port of second channel selection switch
Corresponding emitting mould train the 13rd, 14 external-connected ports.
Wherein, first, third external-connected port is used to connect the signal emission port of RF transceiver, and the five, the 6th is external
Port is used to connect the antenna of corresponding antenna sets, and the seven, the eight, the 9th external-connected ports are for connecting receiving module or being used for
Connecting receiving module and emitting mould train, the tenth external-connected port is used to connect the port power detection PDET of RF transceiver, and the tenth
One external-connected port for the optional power detection channel for connecting other mould groups to realize power detection, second, the four, the 12nd,
13rd, the external-connected port in the 14th external-connected port is used to connect the receiver port of RF transceiver, alternatively, the tenth
Two, the ten three, the external-connected port in the 14th external-connected port is used to connect the external-connected port of other emitting mould trains.
As shown in fig. 2j, which includes 2 road signal transmitting and receiving processing circuits, 1 channel selection switch (including 3P3T
Switch) and 1 power detection selection switch, signal transmitting and receiving processing circuit includes 1 PA, 1 LNA, 1 transceiver toggle switch
(including SPDT switch), 1 filter, 1 power coupler.The emitting mould train even can also include that MIPI and/or GPIO is controlled
Unit processed completes PA/LNA/ power coupler Coupler/ Switch Control.Wherein,
First PA and the first LNA the first transceiver toggle switch of connection, the first transceiver toggle switch connect first filter, the
One filter connects the first power coupler, the 2nd PA and the 2nd LNA the second transceiver toggle switch of connection, and the second transmitting-receiving switching is opened
Connection connects second filter, and second filter connects the second power coupler, and the one the second power couplers connect power detection
Selection switch (including SP3T switch, wherein 1 external-connected port of remaining 1 T-port as emitting mould train, the external-connected port
For n power coupler access of other emitting mould trains to be switched to the output of power coupling path), the one the second power
Coupler is also connected with channel selection switch.
The input port of first PA corresponds to the first external-connected port of emitting mould train, the corresponding transmitting of the output port of the first LNA
Second external-connected port of mould group, the input port of the 2nd PA correspond to the third external-connected port of emitting mould train, the output end of the 2nd LNA
It is the 5th external to correspond to emitting mould train for 4th external-connected port of mouthful corresponding emitting mould train, first port P of channel selection switch
Port, second port P of channel selection switch correspond to the 6th external-connected port of emitting mould train, the third of channel selection switch
The port P corresponds to the 7th external-connected port of emitting mould train, and the port P of power detection selection switch corresponds to outside the 8th of emitting mould train
Connecing port, the remaining T-port of power detection selection switch corresponds to the 9th external-connected port of emitting mould train, and the of channel selection switch
Three T-ports correspond to the tenth external-connected port of emitting mould train.
Wherein, first, third external-connected port is used to connect the signal emission port of RF transceiver, and the five, the 6th is external
Port is used to connect the antennas of corresponding antenna sets, and the 7th external-connected port is for connecting receiving module and/or emitting mould train, and the 8th
External-connected port is used to connect the port power detection PDET of RF transceiver, and the tenth external-connected port is for connecting RF transceiver
The external-connected port of receiver port or other emitting mould trains.
As shown in figure 2k, which includes 1 road signal transmitting and receiving processing circuit, 1 road signal receiving channel, 1 channel
Selection switch (including DP3T switch) and 1 power detection selection switch, signal transmitting and receiving processing circuit includes 1 PA, 1
LNA, 1 transceiver toggle switch (including SPDT switch), 1 filter, 1 power coupler, signal receiving channel include 1
LNA and 1 Filter.The emitting mould train can also include that MIPI and/or GPIO control unit completes PA/LNA/ power coupler
Coupler/ Switch Control.Wherein,
First PA and the first LNA the first transceiver toggle switch of connection, the first transceiver toggle switch connect first filter, the
One filter connects power coupler, the 2nd LNA connection second filter, and power coupler connects power detection selection switch
(including SP3T switch, wherein 1 external-connected port of remaining 1 T-port as emitting mould train, which is used for it
N power coupler access of his emitting mould train is switched to a power coupling path output), power coupler and the second filtering
Device interface channel selection switch.
The input port of first PA corresponds to the first external-connected port of emitting mould train, the corresponding transmitting of the output port of the first LNA
The output port of second external-connected port of mould group, the 2nd LNA corresponds to the third external-connected port of emitting mould train, channel selection switch
First port P corresponds to the 4th external-connected port of emitting mould train, and second port P of channel selection switch corresponds to emitting mould train
The port P of 5th external-connected port, power detection selection switch corresponds to the 6th external-connected port of emitting mould train, and power detection selection is opened
The remaining T-port of pass corresponds to the 7th external-connected port of emitting mould train, and the third T-port of channel selection switch corresponds to emitting mould train
The 8th external-connected port.
Wherein, the first external-connected port is used to connect the signal emission port of RF transceiver, and the four, the 5th external-connected ports are used
In the antenna for connecting corresponding antenna sets, the 6th external-connected port is used to connect the port power detection PDET of RF transceiver, the
Eight external-connected ports are used to connect the receiver port of RF transceiver or the external-connected port of other emitting mould trains.
As shown in figure 2l, which includes 1 road signal transmitting and receiving processing circuit, 1 road signal receiving channel, 1 channel
Selection switch (including 4P4T switch) and 1 power detection selection switch, signal transmitting and receiving processing circuit includes 1 PA, 1
LNA, 1 transceiver toggle switch (including SPDT switch), 1 filter, 1 power coupler, signal receiving channel include 1
LNA and 1 Filter.The emitting mould train can also include that MIPI and/or GPIO control unit completes PA/LNA/ power coupler
Coupler/ Switch Control.Wherein,
First PA and the first LNA the first transceiver toggle switch of connection, the first transceiver toggle switch connect first filter, the
One filter connects power coupler, the 2nd LNA connection second filter, and power coupler connects power detection selection switch
(including SP3T switch, wherein 1 external-connected port of remaining 1 T-port as emitting mould train, which is used for it
N power coupler access of his emitting mould train is switched to a power coupling path output), power coupler and the second filtering
Device interface channel selection switch.
The input port of first PA corresponds to the first external-connected port of emitting mould train, the corresponding transmitting of the output port of the first LNA
The output port of second external-connected port of mould group, the 2nd LNA corresponds to the third external-connected port of emitting mould train, channel selection switch
Oneth the second the three or four port P corresponds to the 4th the 5th the 6th the 7th external-connected port of emitting mould train, and power detection selection is opened
The port P of pass corresponds to the 8th external-connected port of emitting mould train, and the remaining T-port of power detection selection switch corresponds to emitting mould train
9th external-connected port, the three or four T-port of channel selection switch correspond to the ten, the 11st external-connected ports of emitting mould train.
Wherein, the first external-connected port is used to connect the signal emission port of RF transceiver, and the four, the 5th external-connected ports are used
In the antenna for connecting corresponding antenna sets, the six, the 7th external-connected ports are used to connect receiving module and/or other emitting mould trains,
8th external-connected port is used to connect the port power detection PDET of RF transceiver, the external connection end in the 10th the 11st external-connected port
Mouth is for connecting the receiver port of RF transceiver or the external-connected port of other emitting mould trains.
As shown in figure 2m, which includes 2 road signal transmitting and receiving processing circuits, 2 channel selection switches (including DP3T
Switch and 3P3T switch) and 1 power detection selection switch, signal transmitting and receiving processing circuit include 1 PA, 1 LNA, 1 receive
Hair switching switch (including SPDT switch), 1 filter, 1 power coupler.The emitting mould train can also include MIPI and/
Or GPIO control unit completes PA/LNA/ power coupler Coupler/ Switch Control.Wherein,
First PA and the first LNA the first transceiver toggle switch of connection, the first transceiver toggle switch connect first filter, the
One filter connects the first power coupler, the 2nd PA and the 2nd LNA the second transceiver toggle switch of connection, and the second transmitting-receiving switching is opened
Connection connects second filter, and second filter connects the second power coupler, and the one the second power couplers connect power detection
Selection switch (including SP3T switch, wherein 1 external-connected port of remaining 1 T-port as emitting mould train, the external-connected port
For n power coupler access of other emitting mould trains to be switched to the output of power coupling path), the one the second power
Coupler connects first passage selection switch (including DP3T switch), first passage selection switch connection second channel selection switch
(including 3P3T switch).
The input port of first PA corresponds to the first external-connected port of emitting mould train, the corresponding transmitting of the output port of the first LNA
Second external-connected port of mould group, the input port of the 2nd PA correspond to the third external-connected port of emitting mould train, the output end of the 2nd LNA
4th external-connected port of mouthful corresponding emitting mould train, the one the second T-ports of first passage selection switch correspond to the of emitting mould train
5 the 6th external-connected ports, the one the second third external-connected ports of second channel selection switch correspond to the seven the eight the of emitting mould train
Nine external-connected ports, the port P of power detection selection switch correspond to the tenth external-connected port of emitting mould train, power detection selection switch
Remaining T-port (T-port of not connected the one the second power coupler) corresponding emitting mould train the 11st external-connected port, second
Second third T-port of channel selection switch corresponds to the 12nd of emitting mould train the, the 13rd external-connected port.
Wherein, the first third external-connected port is used to connect the signal emission port of RF transceiver, the five, the 6th external connection ends
Mouth is for connecting the antenna of corresponding antenna sets, and the seven, the 8th the 9th external-connected ports are for connecting receiving module and/or other hairs
Penetrate mould group, the tenth external-connected port is used to connect the power sensor port PDET of RF transceiver, and the 2nd the 4th the ten two the 13rd
External-connected port in external-connected port is used to connect the receiver port of RF transceiver, alternatively, the ten two the 13rd external connection end
External-connected port in mouthful is used to connect the external-connected port of other emitting mould trains.
The third aspect, by the definition of receiving module as above and emitting mould train, composition supports the 5G radio frequency frame of electronic equipment
Structure, above-mentioned receiving module and emitting mould train be applied to electronic equipment, as shown in figure 3, the radio frequency system include RF transceiver,
Rf processing circuitry and at least two antenna sets, the RF transceiver connect the rf processing circuitry, the radio frequency processing electricity
Road connects at least two antenna sets;
The radio frequency system supports 4 antenna of downlink receive capabilities simultaneously, and at least two antenna sets include m branch antenna altogether,
M is more than or equal to 4 and is less than or equal to 8, and the rf processing circuitry includes identical with the group number quantity of at least two antenna sets
Mould group, each mould group connects 1 antenna sets, and each mould group, close to the antenna sets setting connected, the mould group includes transmitting
Mould group or emitting mould train and receiving module.
As it can be seen that since each mould group in radio frequency system is arranged close to respective antenna group, and only needing to receive in this example
Mould group and emitting mould train can construct core processing circuit, are conducive to promote each channel sensitivity, build compared to discrete device, collection
At Du Genggao, area/cost/power consumption is more excellent.
In a possible example, when the radio frequency system supports single-shot emission mode, the rf processing circuitry includes 1
A emitting mould train and 2 or 3 receiving modules.
Wherein, the emitting mould train and at least one receiving module are set on mainboard, and remaining receiving module is set to pair
On plate, the remaining receiving module is the receiving module in addition to the receiving module being set on the mainboard.
Wherein, the RF transceiver connects the emitting mould train and 2 or 3 receiving modules.
Wherein, the emitting mould train connects at least one receiving module to support the signal of at least one receiving module to send out
Penetrate function.
In a possible example, when the radio frequency system supports double emission modes, the rf processing circuitry is at least
Including 2 emitting mould trains;
Wherein, 2 emitting mould trains are set on mainboard.
Wherein, the rf processing circuitry further includes 1 or 2 receiving modules, and at least one receiving module is set to pair
On plate.
In a possible example, the RF transceiver connects 2 emitting mould trains;
And/or 2 emitting mould trains have connection relationship;And/or the RF transceiver connects described 1 or 2
A receiving module;And/or emitting mould train connection receiving module is to support the signal of at least one receiving module to emit function
Energy.
In a possible example, the rf processing circuitry further includes at least one receiving port selection switch, each
The receiver port of receiving port selection switch connection RF transceiver, and connection emitting mould train or receiving module.
It describes in detail below with reference to example.
As shown in Figure 3A, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. supporting 4 antenna SRS switching;5. NR 1T4R (1 tunnel emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, Mei Getian
Line group includes 1 antenna, wherein RF transceiver, emitting mould train, the first receiving module are set on mainboard (in respective figure
2 mould groups on the upside of battery), the second receiving module and third receiving module are set on subplate (in respective figure 2 on the downside of battery
Mould group), and each receiving module is close to connected antenna and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, the 4th receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship are as shown in Figure 2 C, and each receiving module includes 1 low
Noise amplifier LNA, 1 filter, (the first switching switch is that SP3T is switched to 2 switching switches, and the second switching switch is
SPDT switch), 1 auxiliary port AUX and the built-in channel Bypass, the of the AUX connection emitting mould train of the first receiving module
Six external-connected ports emit signal to support to receive SRS TX signal or autonomous switching antenna.
First external-connected port of the emission port Nx TX connection emitting mould train of RF transceiver, the first of RF transceiver
Second external-connected port of receiving port Nx RX1 connection emitting mould train, the second receiving port Nx RX2 connection of RF transceiver
The port P of second switching switch of one receiving module, the third receiving port Nx RX3 connection emitting mould train of RF transceiver
9th external-connected port, the 8th external-connected port of the 4th receiving port Nx RX4 connection emitting mould train of RF transceiver.
Second antenna sets connect the port P of the first switching switch (SP3T switch) of the first receiving module, and described first cuts
First port T for changing switch corresponds to the auxiliary port AUX of first receiving module, the auxiliary port connection transmitting mould
Second T-port of the 6th external-connected port of group, the first switching switch connects filter, and the filter connects LNA, institute
State first T-port of the switching switch of LNA connection second (SPDT switch), the third T-port and second of the first switching switch
Switch and the channel Bypass is set between second T-port of switch.Third antenna group connects the first switching of the second receiving module
The port P of switch, the 5th external-connected port of the port the P connection emitting mould train of the second switching switch of second receiving module,
The port P of first switching switch of the 4th antenna sets connection third receiving module, the second of the third receiving module cut
Change the 4th external-connected port of the port the P connection emitting mould train of switch.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is cut in SRS4 days line wheel hairs of execution or autonomous transmission
During changing:
In first transmit cycle, electronic equipment controls first T-port of the second channel selection switch of emitting mould train
It is connected to first port P, emits signal, to support the channel quality of base station sounds respective antenna.
In second transmit cycle, electronic equipment controls first T-port of the second channel selection switch of emitting mould train
It is connected to second port P, emits signal, to support the channel quality of base station sounds respective antenna.
In third transmit cycle, electronic equipment controls first T-port of the second channel selection switch of emitting mould train
It is connected to the port third P, emits signal, to support the channel quality of base station sounds respective antenna.
In 4th transmit cycle, electronic equipment controls first T-port of the second channel selection switch of emitting mould train
It is connected to the 4th port P, emits signal, to support the channel quality of base station sounds respective antenna.
As shown in Figure 3B, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
Support DL CA;4. 4 antenna SRS is supported to emit poll;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein every
A antenna sets include 2 antennas, and RF transceiver, emitting mould train, the first receiving module are set on mainboard (in respective figure
2 mould groups on the upside of battery), the second receiving module and third receiving module are set on subplate (in respective figure 2 on the downside of battery
Mould group), and each receiving module is close to connected antenna and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 G, receiving module
Internal components and connection relationship as shown in the receiving module of Fig. 1 K, the AUX connection emitting mould train of the first receiving module the 9th outside
Port is connect to support to emit by respective antenna SRS TX signal or autonomous switching antenna and emit signal.
First external-connected port of the emission port Nx TX connection emitting mould train of the first frequency range of RF transceiver, the second frequency
The third external-connected port of the emission port Ny TX connection emitting mould train of section, the first receiving end of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of mouth Nx RX1 connection emitting mould train, the second frequency range of RF transceiver connects
The 4th external-connected port of emitting mould train is connect, the second receiving port Nx RX2 connection first of the first frequency range of RF transceiver receives
First port P of the second switching switch of mould group, the second receiving port Ny RX2 connection of the second frequency range of RF transceiver
Second port P of the second switching switch of the first receiving module, the third receiving port Nx of the first frequency range of RF transceiver
14th external-connected port of RX3 connection emitting mould train, the third receiving port Ny RX3 connection of the second frequency range of RF transceiver
Second port P of the second switching switch of the second receiving module, the 4th receiving port Nx of the first frequency range of RF transceiver
13rd external-connected port of RX4 connection emitting mould train, the 4th receiving port Ny RX4 connection of the second frequency range of RF transceiver
Second port P of the second switching switch of third receiving module.The of the port the PDET connection emitting mould train of RF transceiver
Ten external-connected ports.
Second antenna sets connect 2 ports P of the first switching switch (DP4T switch) of the first receiving module, the first switching
First T-port of switch correspond to the auxiliary port of first receiving module, and the auxiliary port connects the of emitting mould train
Nine external-connected ports, first switching switch second T-port connect first filter, first filter connect the first LNA, first
First T-port of the switching switch of LNA connection second (DP3T switch), the third T-port connection second of the first switching switch
Filter, second filter connect the 2nd LNA, second T-port of the 2nd LNA connection second switching switch, and the first switching is opened
The channel Bypass is set between the 4th T-port closed and the third T-port of the second switching switch.
Third antenna group and the second receiving module, the second receiving module internal components connection relationship and aforementioned second antenna with
Second receiving module is similar, the 4th antenna and third receiving module, third receiving module internal components connection relationship and aforementioned the
Two antennas are similar with the second receiving module, and details are not described herein again.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to first port P, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to the port local terminal third P, it is real
Signal is now emitted by the antenna of antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the port third P, and second port P of first T-port and local terminal for controlling second channel selection switch connects
It is logical, it realizes and signal is emitted by the antenna of antenna sets.
In 4th transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the port third P, and first port P of first T-port and local terminal for controlling second channel selection switch connects
It is logical, it realizes and signal is emitted by the antenna of antenna sets.
As shown in Figure 3 C, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
Support DL CA;4. 4 antenna SRS is supported to emit poll;5. NR 2T4R (2 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules and 4 antenna sets, wherein every
A antenna sets include 2 antennas, and RF transceiver, the one the second emitting mould trains are set on mainboard (in respective figure on battery
The mould group of side 2), the first receiving module and the second receiving module are set on subplate (2 mould groups on the downside of battery in respective figure),
And each receiving module is close to connected antenna and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 G, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 K, and details are not described herein again, the 7th external connection end of the first emitting mould train
1 port P of the second switching switch of mouth the second receiving module of connection, the 8th external-connected port connection second of the first emitting mould train
12nd external-connected port of emitting mould train, the 7th external-connected port of the second emitting mould train connect the second switching of the first receiving module
1 port P of switch.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the first external-connected port of second emission port Nx TX2 the second emitting mould train of connection of the first frequency range, the first of the second frequency range
The third external-connected port of emission port Ny TX1 the first emitting mould train of connection, the second emission port Ny TX2 connection of the second frequency range
The third external-connected port of second emitting mould train, the first receiving port Nx RX1 connection first hair of the first frequency range of RF transceiver
Penetrate the second external-connected port of mould group, first receiving port Ny RX1 the first emitting mould train of connection of the second frequency range of RF transceiver
The 4th external-connected port, the second of second receiving port Nx RX2 the second emitting mould train of connection of the first frequency range of RF transceiver
External-connected port, the 4th external-connected port of second receiving port Ny RX2 the second emitting mould train of connection of the second frequency range, the first frequency range
Third receiving port Nx RX3 the second emitting mould train of connection the 13rd external-connected port, the third receiving port Ny of the second frequency range
1 port P of the second switching switch of RX3 the first receiving module of connection, which connects the T-port of Ny UHF band reception access
To realize Ny frequency range third road signal receiving channel, the 4th receiving port Nx RX4 connection of the first frequency range of RF transceiver
13rd external-connected port of one emitting mould train, the second of the 4th receiving port Ny RX4 the second receiving module of connection of the second frequency range
Switch 1 port P of switch, the P port switching to local terminal Ny frequency band signals receiving channel.The port PDET of RF transceiver connects
Connect the tenth external-connected port of emitting mould train.
2 antennas of first antenna group are separately connected the one the second external-connected ports of the first emitting mould train, the second antenna sets
It is similar with the connection relationship of the second emitting mould train.
2 antennas of third antenna group group are separately connected 2 ports P of the first switching switch of the first receiving module, the
Four antenna sets are similar with the connection relationship of the second receiving module.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
SRS4 days line wheel hairs or autonomous transmission switching (are held suitable for user or antenna are blocked, influence the field of antenna uplink transmission
Scape) during:
In first transmit cycle, electronic equipment controls first T of the first passage selection switch of the first emitting mould train
Port is connected to first port P, emits signal, while controlling first T-port and third P of first passage selection switch
Port connection, and first T-port for controlling second channel selection switch is connected to first port P of local terminal, emits signal, it is real
Signal is now emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T of the first passage selection switch of the second emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the second emitting mould train switchs
T-port is connected to the port third P, and controls first T-port and first end P of local terminal of local terminal second channel selection switch
Mouth connection, emits signal, realizes the antenna transmitting signal by antenna sets.
In addition, this radio architectures is compatible with 1T4R SRS switching, that is, support to be dealt into 4 days from the first emitting mould train wheel
The ability of line group, i.e. the one the second transmit cycles are the first emitting mould trains by the 5th external-connected port or the 6th external-connected port, then
7th external-connected port;It is the 8th external-connected port out into the 12nd external connection end of the second emitting mould train in third transmit cycle
For second channel of making a slip of the tongue selection switch to the second antenna sets, the 4th transmit cycle is that the 8th external-connected port of the first emitting mould train goes out
The first second channel selection switch is made a slip of the tongue again to the first receiving module come the 12nd external connection end into the second emitting mould train.
As shown in Figure 3D, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
Support DL CA;4. supporting SRS4 days line wheel hairs;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein every
A antenna sets include 2 antennas, and RF transceiver, emitting mould train, the first receiving module are set on mainboard, and second receives mould
Group and third receiving module are set on subplate, and each receiving module is close to connected antenna and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 H, receiving module
Internal components and connection relationship as shown in the receiving module of Fig. 1 K, the AUX connection emitting mould train of the first receiving module the 9th outside
Port is connect to support to emit by respective antenna SRS TX signal or autonomous switching antenna and emit signal.
First external-connected port of the emission port Nx TX connection emitting mould train of the first frequency range of RF transceiver, the second frequency
The third external-connected port of the emission port Ny TX connection emitting mould train of section, the first receiving end of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of mouth Nx RX1 connection emitting mould train, the second frequency range of RF transceiver connects
The 4th external-connected port of emitting mould train is connect, the second receiving port Nx RX2 connection first of the first frequency range of RF transceiver receives
First port P of the second switching switch of mould group, the second receiving port Ny RX2 connection of the second frequency range of RF transceiver
Second port P of the second switching switch of the first receiving module, the third receiving port Nx of the first frequency range of RF transceiver
15th external-connected port of RX3 connection emitting mould train, the third receiving port Ny RX3 connection of the second frequency range of RF transceiver
Second port P of the second switching switch of the second receiving module, the 4th receiving port Nx of the first frequency range of RF transceiver
14th external-connected port of RX4 connection emitting mould train, the 4th receiving port Ny RX4 connection of the second frequency range of RF transceiver
Second port P of the second switching switch of third receiving module.The of the port the PDET connection emitting mould train of RF transceiver
Ten external-connected ports.
Second antenna sets connect 2 ports P of the first switching switch (DP4T switch) of the first receiving module, the first switching
First T-port of switch correspond to the auxiliary port of first receiving module, and the auxiliary port connects the of emitting mould train
Nine external-connected ports, first switching switch second T-port connect first filter, first filter connect the first LNA, first
First T-port of the switching switch of LNA connection second (DP3T switch), the third T-port connection second of the first switching switch
Filter, second filter connect the 2nd LNA, second T-port of the 2nd LNA connection second switching switch, and the first switching is opened
The channel Bypass is set between the 4th T-port closed and the third T-port of the second switching switch.
Third antenna group and the second receiving module, the second receiving module internal components connection relationship and aforementioned second antenna with
Second receiving module is similar, the 4th antenna and third receiving module, third receiving module internal components connection relationship and aforementioned the
Two antennas are similar with the second receiving module, and details are not described herein again.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to transmitting signal with first port P, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and the port P for controlling second channel selection switch is connected to local terminal third T-port, transmitting letter
Number, it realizes and signal is emitted by the antenna of antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the port third P, and the port P for controlling second channel selection switch is connected to second T-port of local terminal, is emitted
Signal is realized and emits signal by the antenna of antenna sets.
In 4th transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the 4th port P, and the port P for controlling second channel selection switch is connected to first T-port of local terminal, is emitted
Signal is realized and emits signal by the antenna of antenna sets.
As shown in FIGURE 3 E, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
Support DL CA;4. supporting SRS4 days line wheel hairs;5. NR 2T4R (2 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules and 4 antenna sets, wherein every
A antenna sets include 2 antennas, and RF transceiver, the one the second emitting mould trains are set on mainboard (in respective figure on battery
The mould group of side 2), the first receiving module and the second receiving module are set on subplate (2 mould groups on the downside of battery in respective figure),
And each receiving module is close to connected antenna and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components of receiving module and connection relationship are as shown in the receiving module of Fig. 1 K, and details are not described herein again.Hair
The internal components structure and connection relationship for penetrating mould group are not repeating, the first emitting mould train herein as shown in the emitting mould train of Fig. 2 H
The 8th external-connected port connect the second emitting mould train the 13rd external-connected port.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the first external-connected port of second emission port Nx TX2 the second emitting mould train of connection of the first frequency range, the first of the second frequency range
The third external-connected port of emission port Ny TX1 the first emitting mould train of connection, the second emission port Ny TX2 connection of the second frequency range
The third external-connected port of second emitting mould train, the first receiving port Nx RX1 connection first hair of the first frequency range of RF transceiver
Penetrate the second external-connected port of mould group, first receiving port Ny RX1 the first emitting mould train of connection of the second frequency range of RF transceiver
The 4th external-connected port, the second of second receiving port Nx RX2 the second emitting mould train of connection of the first frequency range of RF transceiver
External-connected port, the 4th external-connected port of second receiving port Ny RX2 the second emitting mould train of connection of the second frequency range, the first frequency range
Third receiving port Nx RX3 the second emitting mould train of connection the 12nd external-connected port, the third receiving port Ny of the second frequency range
1 port P of the second switching switch of RX3 the first receiving module of connection, which connects the T-port of Ny UHF band reception access
To realize Ny frequency range third road signal receiving channel, the 4th receiving port Nx RX4 connection of the first frequency range of RF transceiver
12nd external-connected port of one emitting mould train, the second of the 4th receiving port Ny RX4 the second receiving module of connection of the second frequency range
Switch 1 port P of switch, the P port switching to local terminal Ny frequency band signals receiving channel.The port PDET of RF transceiver connects
Connect the tenth external-connected port of emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
It is similar with the connection relationship of the second emitting mould train.
2 antennas of third antenna group group are separately connected 2 ports P of the first switching switch of the first receiving module, the
Four antenna sets are similar with the connection relationship of the second receiving module.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T of the first passage selection switch of the first emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the first emitting mould train switchs
T-port is connected to the port third P, and the port P for controlling second channel selection switch is connected to first T-port of local terminal, is sent out
Signal is penetrated, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T of the first passage selection switch of the second emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the second emitting mould train switchs
T-port is connected to the port third P, and first T-port in the port P and local terminal for controlling local terminal second channel selection switch connects
It is logical, emit signal, realizes and signal is emitted by the antenna of antenna sets.
In addition, this radio architectures is compatible with 1T4R SRS switching, that is, support to be dealt into 4 days from the first emitting mould train wheel
The ability of line group, i.e. the one the second transmit cycles are that the first emitting mould train passes through the 5th external-connected port and the 7th external-connected port;?
In third transmit cycle, be the 8th external-connected port come out into the second emitting mould train the 12nd external connection end make a slip of the tongue first passage selection
Switch is that the 8th external-connected port of the first emitting mould train comes out into the second emitting mould train to the second antenna sets, the 4th transmit cycle
The 14th external connection end make a slip of the tongue the first second channel selection switch again to the first receiving module.
As illustrated in Figure 3 F, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
DL CA is not supported;4. supporting 4 antenna SRS switching;5. NR 1T4R (1 tunnel emits 4 tunnels and receives).
The 5G radio architectures include that RF transceiver, 1 emitting mould train, 3 receiving modules, the selection of 1 receiving port are opened
Close (including SPDT switch), 4 antenna sets, wherein RF transceiver, emitting mould train, the one the second receiving modules, receiving end
Mouth selection switch is set on mainboard (2 mould groups on the upside of battery in respective figure), and it is (right that third receiving module is set on subplate
Answer the 2 mould groups in battery downside in attached drawing), and each receiving module is close to connected antenna and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group group, the 4th receiving module is arranged close to the 4th antenna sets.
Wherein, as shown in figure 2i, each receiving module is such as Fig. 1 L for the internal components structure of emitting mould train and connection relationship
Shown in receiving module.The first AUX (1 AUX of connection the first switching switch) connection transmitting mould of the one the second receiving modules
Nine, the 8th external-connected ports of group are to support to emit by respective antenna SRS TX signal or autonomous switching antenna transmitting letter
Number, the first AUX of third receiving module (AUX of connection the second switching switch) connection the 2nd AUX (in addition any 1 AUX) with
Support transmission SRS TX signal.
First external-connected port of the emission port Nx TX connection emitting mould train of the first frequency range of RF transceiver, the second frequency
The third external-connected port of the emission port Ny TX connection emitting mould train of section, the first receiving end of the first frequency range of RF transceiver
Second receiving port Nx RX2 of the second external-connected port of mouth Nx RX1 connection emitting mould train, the first frequency range of RF transceiver connects
Connect first port P of the second switching switch of the first receiving module, the third receiving port of the first frequency range of RF transceiver
First port P of the second switching switch of Nx RX3 the second receiving module of connection, the first of the second frequency range of RF transceiver
4th external-connected port of receiving port Ny RX1 connection emitting mould train, the second receiving port Ny of the second frequency range of RF transceiver
Second port P of the second switching switch of RX2 the first receiving module of connection, the third of the second frequency range of RF transceiver receive
Second port P of the second switching switch of port Ny RX3 the second receiving module of connection, the first frequency range of RF transceiver
2 ends T of 4th receiving port Nx RX4 and the 4th receiving port Ny RX4 connection receiving port of the second frequency range selection switch
Mouthful, the 13rd external-connected port of the port the P connection emitting mould train of receiving port selection switch, the port PDET of RF transceiver
Connect the tenth external-connected port of emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas connect the first receiving module the first switching switch 2 ports P, third antenna group group and the second receiving module
Connection relationship it is similar, the 4th antenna sets are similar with the connection relationship of third receiving module.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch: in first transmit cycle, electronic equipment controls emitting mould train
First T-port of first passage selection switch is connected to first port P, is emitted signal, is realized the antenna by antenna sets
Emit signal.
In second transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to the port third P, is realized logical
Cross the antenna transmitting signal of antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to second port P, transmitting letter
Number, it realizes and signal is emitted by the antenna of antenna sets.
In 4th transmit cycle, electronic equipment controls first T-port of the second channel selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P, transmitting letter
Number, it realizes and signal is emitted by the antenna of antenna sets.
As shown in Figure 3 G, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
DL CA is not supported;4. supporting 4 antenna SRS switching;5. NR 1T4R (1 tunnel emits 4 tunnels and receives).
The 5G radio architectures include that RF transceiver, 1 emitting mould train, 3 receiving modules, the selection of 2 receiving ports are opened
Close (including SPDT switch), 4 antenna sets, wherein RF transceiver, emitting mould train, the first receiving module, 2 receiving ports
Selection switch is set on mainboard (2 mould groups on the upside of battery in respective figure), and the second third receiving module is set on subplate
(2 mould groups on the downside of battery in respective figure), and each receiving module is close to connected antenna and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, the 4th receiving module is arranged close to the 4th antenna sets.
Wherein, as shown in figure 2i, each receiving module is such as Fig. 1 L for the internal components structure of emitting mould train and connection relationship
Shown in receiving module.Outside the 9th of the aux port connection emitting mould train of 1 connection the first switching switch of first receiving module
Port is connect to support to emit by respective antenna SRS TX signal or autonomous switching antenna and emit signal, the second third receives mould
The first AUX (AUX of connection the second switching switch) connection the 2nd AUX (in addition any 1 AUX) of group is to support transmission SRS
TX signal.
First external-connected port of the emission port Nx TX connection emitting mould train of the first frequency range of RF transceiver, the second frequency
The third external-connected port of the emission port Ny TX connection emitting mould train of section, the first receiving end of the first frequency range of RF transceiver
Second receiving port Nx RX2 of the second external-connected port of mouth Nx RX1 connection emitting mould train, the first frequency range of RF transceiver connects
Connect first port P of the second switching switch of the first receiving module, the first receiving port of the second frequency range of RF transceiver
4th external-connected port of Ny RX1 connection emitting mould train, the second receiving port Ny RX2 connection of the second frequency range of RF transceiver
Second port P of the second switching switch of the first receiving module, the third receiving port Nx of the first frequency range of RF transceiver
2 T-ports of third receiving port Ny RX3 connection connection the first receiving port selection switch of RX3 and the second frequency range, first
14th external-connected port of the port the P connection emitting mould train of receiving port selection switch, the of the first frequency range of RF transceiver
2 T of four receiving port Nx RX4 and the 4th receiving port Ny RX4 the second receiving port of connection of the second frequency range selection switch
Port, the 13rd external-connected port of the port the P connection emitting mould train of the second receiving port selection switch, the PDET of RF transceiver
Tenth external-connected port of port connection emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas connect the first receiving module the first switching switch 2 ports P, third antenna group and the second receiving module
Connection relationship is similar, and the 4th antenna sets are similar with the connection relationship of third receiving module.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch: in first transmit cycle, electronic equipment controls emitting mould train
First T-port of first passage selection switch is connected to first port P, is realized and is emitted signal by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to the port third P, is realized logical
Cross the antenna transmitting signal of antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to second port P, is realized logical
Cross the antenna transmitting signal of antenna sets.
In 4th transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P, is realized logical
Cross the antenna transmitting signal of antenna sets.
As shown in figure 3h, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
DL CA is not supported;4. supporting 4 antenna SRS switching;5. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive).
The 5G radio architectures include that RF transceiver, 2 emitting mould trains, 2 receiving modules, the selection of 2 receiving ports are opened
Close (including SPDT switch), 4 antenna sets, wherein RF transceiver, the one the second emitting mould trains, 2 receiving ports selections
Switch is set on mainboard (in respective figure battery on the upside of 2 mould groups), and the one the second receiving modules are set on subplate (corresponding
2 mould groups on the downside of battery in attached drawing), and each receiving module is close to connected antenna and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, as shown in figure 2i, each receiving module is such as Fig. 1 L for the internal components structure of emitting mould train and connection relationship
Shown in receiving module.The first AUX (AUX of connection the second switching switch) the 2nd AUX of connection of the one the second receiving modules is (another
Outer any 1 AUX) to support to transmit SRS TX signal, the 8th external-connected port of the first emitting mould train connects the second emitting mould train
The 12nd external-connected port.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range, the of RF transceiver
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of one frequency range, the second transmitting terminal of the second frequency range
The third external-connected port of mouth Ny TX2 the second emitting mould train of connection, the first receiving port Nx of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of RX1 the first emitting mould train of connection, the second frequency range of RF transceiver connects
Connect the 4th external-connected port of the first emitting mould train, the second receiving port Nx RX2 connection second of the first frequency range of RF transceiver
Second receiving port Ny RX2 connection second of the second external-connected port of emitting mould train, the second frequency range of RF transceiver emits mould
4th external-connected port of group, the third receiving port Nx RX3 of the first frequency range of RF transceiver and the third of the second frequency range receive
Port Ny RX3 connection connects 2 T-ports of the first receiving port selection switch, the port P of the first receiving port selection switch
Connect the 14th external-connected port of the second emitting mould train, the 4th receiving port Nx RX4 of the first frequency range of RF transceiver and
2 T-ports of the 4th receiving port Ny RX4 the second receiving port of connection selection switch of two frequency ranges, the selection of the second receiving port
The port P of switch connects the 14th external-connected port of the first emitting mould train, and the port PDET of RF transceiver connects emitting mould train
The tenth external-connected port.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas connect the second emitting mould train the 5th the 6th external-connected port, third antenna group 2 antennas connection first receive mould
2 ports P of the first switching switch of group, 2 antennas of the 4th antenna sets connect the first switching switch of the second receiving module
2 ports P.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T of the first passage selection switch of the first emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the first emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T of the first passage selection switch of the second emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the second emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
In addition, this radio architectures is compatible with 1T4R SRS switching, that is, support to be dealt into 4 days from the first emitting mould train wheel
The ability of line group, i.e. the one the second transmit cycles are that the first emitting mould train passes through the 5th external-connected port and the 7th external-connected port;?
In third transmit cycle, be the 8th external-connected port come out into the second emitting mould train the 13rd external connection end make a slip of the tongue first passage selection
Switch is that the 8th external-connected port of the first emitting mould train comes out into the second emitting mould train to the second antenna sets, the 4th transmit cycle
The 13rd external connection end make a slip of the tongue second channel selection switch again to the first receiving module.
As shown in fig. 31, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
DL CA is not supported;4. supporting 4 antenna SRS switching;5. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive).
The 5G radio architectures include that RF transceiver, 2 emitting mould trains, 2 receiving modules, the selection of 1 receiving port are opened
Close (including SPDT switch), 4 antenna sets, wherein RF transceiver, the first receiving module, connects the one the second emitting mould trains
It receives port selection switch and is set on mainboard (2 mould groups on the upside of battery in respective figure), the second receiving module is set to subplate
Upper (2 mould groups on the downside of battery in respective figure), and each receiving module is close to connected antenna and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, as shown in figure 2i, each receiving module is such as Fig. 1 L for the internal components structure of emitting mould train and connection relationship
Shown in receiving module.The first AUX (AUX of connection the first switching switch) second emitting mould train of connection of first receiving module
7th external-connected port is to support to emit by respective antenna SRS TX signal, and the 2nd AUX of the first receiving module (cut by connection first
Change another AUX of switch) the 8th external-connected port of the first emitting mould train is connected to support to emit SRS TX by respective antenna
Signal or autonomous switching antenna emit signal, and the first AUX (connecting the AUX of the second switching switch) of the second receiving module is even
It meets the 2nd AUX (connecting any 1 AUX of the first switching switch) and SRS TX signal is transmitted with support, the first emitting mould train
9th external-connected port connects the 12nd external-connected port of the second emitting mould train.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range, the of RF transceiver
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of one frequency range, the second transmitting terminal of the second frequency range
The third external-connected port of mouth Ny TX2 the second emitting mould train of connection, the first receiving port Nx of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of RX1 the first emitting mould train of connection, the second frequency range of RF transceiver connects
Connect the 4th external-connected port of the first emitting mould train, the second receiving port Nx RX2 connection second of the first frequency range of RF transceiver
Second receiving port Ny RX2 connection second of the second external-connected port of emitting mould train, the second frequency range of RF transceiver emits mould
4th external-connected port of group, the of third receiving port Nx RX3 the first receiving module of connection of the first frequency range of RF transceiver
First port P of two switching switches, the third receiving port Ny RX3 connection first of the second frequency range of RF transceiver receive
Second port P of the second switching switch of mould group, the 4th receiving port Nx RX4 of the first frequency range of RF transceiver and the
2 T-ports of the 4th receiving port Ny RX4 connection receiving port selection switch of two frequency ranges, the P of receiving port selection switch
Port connects the 14th external-connected port of the first emitting mould train, and the port PDET of RF transceiver connects the of the first emitting mould train
Ten external-connected ports.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas connect the second emitting mould train the 5th the 6th external-connected port, third antenna group 2 antennas connection first receive mould
2 ports P of the first switching switch of group, 2 antennas of the 4th antenna sets connect the first switching switch of the second receiving module
2 ports P.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T of the first passage selection switch of the first emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the first emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T of the first passage selection switch of the second emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the second emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
In addition, this radio architectures is compatible with 1T4R SRS switching, that is, support to be dealt into 4 days from the first emitting mould train wheel
The ability of line group, i.e. the one the second transmit cycles are that the first emitting mould train passes through the 5th external-connected port and the 7th external-connected port;?
In third transmit cycle, be the 9th external-connected port come out into the second emitting mould train the 12nd external connection end make a slip of the tongue first passage selection
Switch is that the 8th external-connected port of the first emitting mould train comes out into the first receiving module to the second antenna sets, the 4th transmit cycle
Auxiliary port.
As shown in figure 3j, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
Support DL CA;4. supporting SRS4 days line wheel hairs;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein every
A antenna sets include 2 antennas, and RF transceiver, emitting mould train, the first receiving module and the second receiving module are set to mainboard
On, third receiving module is set on subplate, and emitting mould train and each receiving module are close to connected antenna and place.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 I, receiving module
Internal components and connection relationship as shown in the receiving module of Fig. 1 L, the AUX connection emitting mould train of the first receiving module the 9th outside
Port is connect to support to emit by respective antenna SRS TX signal or autonomous switching antenna and emit signal, the second receiving module
AUX connection emitting mould train the 8th external-connected port to support to emit SRS TX signal by respective antenna or independently switch day
Line emits signal, and other any 1 AUX of AUX connection of the switching switch of connection second of third receiving module is to support transmission SRS
TX signal.
First external-connected port of the emission port Nx TX connection emitting mould train of the first frequency range of RF transceiver, the second frequency
The third external-connected port of the emission port Ny TX connection emitting mould train of section, the first receiving end of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of mouth Nx RX1 connection emitting mould train, the second frequency range of RF transceiver connects
The 4th external-connected port of emitting mould train is connect, the second receiving port Nx RX2 connection first of the first frequency range of RF transceiver receives
First port P of the second switching switch of mould group, the second receiving port Ny RX2 connection of the second frequency range of RF transceiver
Second port P of the second switching switch of the first receiving module, the third receiving port Nx of the first frequency range of RF transceiver
First port P of the second switching switch of RX3 the second receiving module of connection, the third of the second frequency range of RF transceiver receive
Second port P of the second switching switch of port Ny RX3 the second receiving module of connection, the first frequency range of RF transceiver
13rd external-connected port of the 4th receiving port Nx RX4 connection emitting mould train, the 4th of the second frequency range of RF transceiver receive
First port P of the second switching switch of port Ny RX4 connection third receiving module.The port PDET of RF transceiver connects
Connect the tenth external-connected port of emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of emitting mould train, and 2 of the second antenna sets
Antenna is separately connected 2 ports P of the first switching switch of the first receiving module, and 2 antennas of third antenna group are separately connected
2 ports P of the first switching switch of the second receiving module, 2 antennas of the 4th antenna sets are separately connected third receiving module
First switching switch 2 ports P.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to transmitting signal with first port P, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first port P for controlling second channel selection switch is connected to local terminal third T-port, is sent out
Signal is penetrated, realizes and signal is emitted by the antenna of antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the port third P, and second T-port in first port P and local terminal for controlling second channel selection switch connects
It is logical, emit signal, realizes and signal is emitted by the antenna of antenna sets.
In 4th transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the port third P, and first T-port in first port P and local terminal for controlling second channel selection switch connects
It is logical, emit signal, realizes and signal is emitted by the antenna of antenna sets.
As shown in Fig. 3 K, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
Support DL CA;4. supporting SRS4 days line wheel hairs;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein every
A antenna sets include 2 antennas, and RF transceiver, emitting mould train, the first receiving module are set on mainboard, and second receives mould
Group and third receiving module are set on subplate, and emitting mould train and each receiving module are close to connected antenna and place.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 I, receiving module
Internal components and connection relationship as shown in the receiving module of Fig. 1 L, the AUX connection emitting mould train of the first receiving module the 9th outside
Port is connect to support to emit by respective antenna SRS TX signal or autonomous switching antenna and emit signal, the second receiving module
Connection second switching switch AUX connection in addition any 1 AUX with support transmit SRS TX signal, third receiving module
Other any 1 AUX of AUX connection of connection the second switching switch is to support transmission SRS TX signal.
First external-connected port of the emission port Nx TX connection emitting mould train of the first frequency range of RF transceiver, the second frequency
The third external-connected port of the emission port Ny TX connection emitting mould train of section, the first receiving end of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of mouth Nx RX1 connection emitting mould train, the second frequency range of RF transceiver connects
The 4th external-connected port of emitting mould train is connect, the second receiving port Nx RX2 connection first of the first frequency range of RF transceiver receives
First port P of the second switching switch of mould group, the second receiving port Ny RX2 connection of the second frequency range of RF transceiver
Second port P of the second switching switch of the first receiving module, the third receiving port Nx of the first frequency range of RF transceiver
First port P of the second switching switch of RX3 the second receiving module of connection, the third of the second frequency range of RF transceiver receive
14th external-connected port of port Ny RX3 connection emitting mould train, the 4th receiving port Nx of the first frequency range of RF transceiver
13rd external-connected port of RX4 connection emitting mould train, the 4th receiving port Ny RX4 connection of the second frequency range of RF transceiver
First port P of the second switching switch of third receiving module.The of the port the PDET connection emitting mould train of RF transceiver
Ten external-connected ports.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of emitting mould train, and 2 of the second antenna sets
Antenna is separately connected 2 ports P of the first switching switch of the first receiving module, and 2 antennas of third antenna group are separately connected
2 ports P of the first switching switch of the second receiving module, 2 antennas of the 4th antenna sets are separately connected third receiving module
First switching switch 2 ports P.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to transmitting signal with first port P, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first port P for controlling second channel selection switch is connected to local terminal third T-port, is sent out
Signal is penetrated, realizes and signal is emitted by the antenna of antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the port third P, and second T-port in first port P and local terminal for controlling second channel selection switch connects
It is logical, emit signal, realizes and signal is emitted by the antenna of antenna sets.
In 4th transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the port third P, and first T-port in first port P and local terminal for controlling second channel selection switch connects
It is logical, emit signal, realizes and signal is emitted by the antenna of antenna sets.
As shown in figure 3l, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
Support DL CA;4. supporting 4 antenna SRS switching;5. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive, and compatible NR 1T4R).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules, 4 antenna sets, wherein are penetrated
Frequency transceiver, the first emitting mould train, the second emitting mould train are set on mainboard, the first receiving module and the setting of the second receiving module
In on subplate, and each emitting mould train and each receiving module are close to connected antenna and place.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, as shown in figure 2i, each receiving module is such as Fig. 1 L for the internal components structure of emitting mould train and connection relationship
Shown in receiving module.Other any 1 AUX of AUX connection of the switching switch of connection second of first receiving module is to support to pass
Defeated SRS TX signal, other any 1 AUX of AUX connection of the switching switch of connection second of the second receiving module is to support to transmit
SRS TX signal.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range, the of RF transceiver
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of one frequency range, the second transmitting terminal of the second frequency range
The third external-connected port of mouth Ny TX2 the second emitting mould train of connection, the first receiving port Nx of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of RX1 the first emitting mould train of connection, the second frequency range of RF transceiver connects
Connect the 4th external-connected port of the first emitting mould train, the second receiving port Nx RX2 connection second of the first frequency range of RF transceiver
Second receiving port Ny RX2 connection second of the second external-connected port of emitting mould train, the second frequency range of RF transceiver emits mould
4th external-connected port of group, the of third receiving port Nx RX3 the second emitting mould train of connection of the first frequency range of RF transceiver
13 external-connected ports, the second of third receiving port Ny RX3 the first receiving module of connection of the second frequency range of RF transceiver cut
Change first port P of switch, the 4th receiving port Nx RX4 the first emitting mould train of connection of the first frequency range of RF transceiver
The 13rd external-connected port, the of the 4th receiving port Ny RX4 the second receiving module of connection of the second frequency range of RF transceiver
First port P of two switching switches, the tenth of the first emitting mould train of the first port PDET1 connection of RF transceiver are external
Port, the 2nd port PDET2 of RF transceiver connect the tenth external-connected port of the second emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas be separately connected the 5th the 6th external-connected port of the second emitting mould train, 2 antennas of third antenna group are separately connected
2 ports P of the first switching switch of one receiving module, 2 antennas of the 4th antenna sets are separately connected the second receiving module
2 ports P of the first switching switch.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T of the first passage selection switch of the first emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the first emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T of the first passage selection switch of the second emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the second emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
In addition, this radio architectures is compatible with 1T4R SRS switching, that is, support to be dealt into 4 days from the first emitting mould train wheel
The ability of line group, i.e. the one the second transmit cycles are that the first emitting mould train passes through the 5th external-connected port and the 7th external-connected port;?
In third transmit cycle, be the 8th external-connected port come out into the second emitting mould train the 12nd external connection end make a slip of the tongue first passage selection
Switch is that the 9th external-connected port of the first emitting mould train comes out into the second emitting mould train to the second antenna sets, the 4th transmit cycle
The 14th external connection end make a slip of the tongue second channel selection switch again to the first receiving module.
As shown in fig.3m, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
Support DL CA;4. supporting 4 antenna SRS switching;5. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive, and compatible NR 1T4R).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules, 4 antenna sets, wherein are penetrated
Frequency transceiver, the first emitting mould train, the second emitting mould train and the first receiving module are set on mainboard, the setting of the second receiving module
In on subplate, and each emitting mould train and each receiving module are close to connected antenna and place.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, as shown in figure 2i, each receiving module is such as Fig. 1 L for the internal components structure of emitting mould train and connection relationship
Shown in receiving module.(first aux port connects the of the first receiving module to first aux port of the first receiving module
One switching switch) connection the second emitting mould train the 7th external-connected port with support by respective antenna emit SRS TX signal or
Autonomous switching antenna emits signal, and (the second aux port connection first receives mould to the second aux port of the first receiving module
First switching switch of group) the 8th external-connected port of the first emitting mould train is connected to support to emit SRS TX letter by respective antenna
Number or autonomous switching antenna emit signal, the AUX connection other any 1 of the switching switch of connection second of the second receiving module
A AUX is to support transmission SRS TX signal, the 9th external-connected port of the first emitting mould train to connect the 12nd of the second emitting mould train the
External-connected port is to support transmission SRS TX signal.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range, the of RF transceiver
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of one frequency range, the second transmitting terminal of the second frequency range
The third external-connected port of mouth Ny TX2 the second emitting mould train of connection, the first receiving port Nx of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of RX1 the first emitting mould train of connection, the second frequency range of RF transceiver connects
Connect the 4th external-connected port of the first emitting mould train, the second receiving port Nx RX2 connection second of the first frequency range of RF transceiver
Second receiving port Ny RX2 connection second of the second external-connected port of emitting mould train, the second frequency range of RF transceiver emits mould
4th external-connected port of group, the of third receiving port Nx RX3 the first receiving module of connection of the first frequency range of RF transceiver
First port P of two switching switches, the third receiving port Ny RX3 connection first of the second frequency range of RF transceiver receive mould
Second port P of the second switching switch of group, the 4th receiving port Nx RX4 connection of the first frequency range of RF transceiver the
4th receiving port Ny RX4 connection second of the 13rd external-connected port of one emitting mould train, the second frequency range of RF transceiver connects
First port P of the second switching switch of mould group is received, the first port PDET1 of RF transceiver connects the first emitting mould train
Tenth external-connected port, the 2nd port PDET2 of RF transceiver connect the tenth external-connected port of the second emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas be separately connected the 5th the 6th external-connected port of the second emitting mould train, 2 antennas of third antenna group are separately connected
2 ports P of the first switching switch of one receiving module, 2 antennas of the 4th antenna sets are separately connected the second receiving module
2 ports P of the first switching switch.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T of the first passage selection switch of the first emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the first emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T of the first passage selection switch of the second emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the second emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
It realizes and signal is emitted by the antenna of antenna sets.
In addition, this radio architectures is compatible with 1T4R SRS switching, that is, support to be dealt into 4 days from the first emitting mould train wheel
The ability of line group, i.e. the one the second transmit cycles are that the first emitting mould train passes through the 5th external-connected port and the 7th external-connected port;?
In third transmit cycle, be the 9th external-connected port come out into the second emitting mould train the 12nd external connection end make a slip of the tongue first passage selection
Switch is that the 8th external-connected port of the first emitting mould train comes out into the first receiving module to the second antenna sets, the 4th transmit cycle
Auxiliary port.
As shown in Fig. 3 N, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
DL CA is not supported;4. supporting SRS4 days line wheel hairs;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules, 4 antenna sets and 1 reception
Port selection switch (including SPDT switch), wherein each antenna sets include 2 antennas, RF transceiver, emitting mould train, the
One receiving module, the second receiving module and receiving port selection switch are set on mainboard, and third receiving module is set to subplate
On, and emitting mould train and each receiving module are close to connected antenna and place.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 M, receiving module
Internal components and connection relationship as shown in the receiving module of Fig. 1 L, the AUX connection emitting mould train of the first receiving module the 9th outside
Port is connect to support to emit by respective antenna SRS TX signal or autonomous switching antenna and emit signal, the second receiving module
AUX connection emitting mould train the 8th external-connected port to support to emit SRS TX signal by respective antenna or independently switch day
Line emits signal, and other any 1 AUX of AUX connection of the switching switch of connection second of third receiving module is to support transmission SRS
TX signal.
First external-connected port of the emission port Nx TX connection emitting mould train of the first frequency range of RF transceiver, the second frequency
The third external-connected port of the emission port Ny TX connection emitting mould train of section, the first receiving end of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of mouth Nx RX1 connection emitting mould train, the second frequency range of RF transceiver connects
The 4th external-connected port of emitting mould train is connect, the second receiving port Nx RX2 connection first of the first frequency range of RF transceiver receives
First port P of the second switching switch of mould group, the second receiving port Ny RX2 connection of the second frequency range of RF transceiver
Second port P of the second switching switch of the first receiving module, the third receiving port Nx of the first frequency range of RF transceiver
First port P of the second switching switch of RX3 the second receiving module of connection, the third of the second frequency range of RF transceiver receive
Second port P of the second switching switch of port Ny RX3 the second receiving module of connection, the first frequency range of RF transceiver
2 ends T of 4th receiving port Nx RX4 and the 4th receiving port Ny RX4 connection receiving port of the second frequency range selection switch
Mouthful, the 12nd external-connected port of the port the P connection emitting mould train of receiving port selection switch, the port PDET of RF transceiver connects
Connect the tenth external-connected port of emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of emitting mould train, and 2 of the second antenna sets
Antenna is separately connected 2 ports P of the first switching switch of the first receiving module, and 2 antennas of third antenna group are separately connected
2 ports P of the first switching switch of the second receiving module, 2 antennas of the 4th antenna sets are separately connected third receiving module
First switching switch 2 ports P.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to transmitting signal with first port P, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first port P for controlling second channel selection switch is connected to local terminal third T-port, is sent out
Signal is penetrated, realizes and signal is emitted by the antenna of antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the port third P, and second T-port in first port P and local terminal for controlling second channel selection switch connects
It is logical, emit signal, realizes and signal is emitted by the antenna of antenna sets.
In 4th transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the port third P, and first T-port in first port P and local terminal for controlling second channel selection switch connects
It is logical, emit signal, realizes and signal is emitted by the antenna of antenna sets.
As shown in Fig. 3 O, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
DL CA is not supported;4. supporting SRS4 days line wheel hairs;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules, 4 antenna sets and 2 receptions
Port selection switch (including SPDT switch), wherein each antenna sets include 2 antennas, RF transceiver, emitting mould train, the
One receiving module, the first receiving port selection switch and the second receiving port selection switch are set on mainboard, and second receives mould
Group, third receiving module are set on subplate, and emitting mould train and each receiving module are close to connected antenna and place.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 M, receiving module
Internal components and connection relationship as shown in the receiving module of Fig. 1 L, the AUX connection emitting mould train of the first receiving module the 9th outside
Port is connect to support to emit by respective antenna SRS TX signal or autonomous switching antenna and emit signal, the second receiving module
Connection second switching switch AUX connection in addition any 1 AUX with support transmit SRS TX signal, third receiving module
Other any 1 AUX of AUX connection of connection the second switching switch is to support transmission SRS TX signal.
First external-connected port of the emission port Nx TX connection emitting mould train of the first frequency range of RF transceiver, the second frequency
The third external-connected port of the emission port Ny TX connection emitting mould train of section, the first receiving end of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of mouth Nx RX1 connection emitting mould train, the second frequency range of RF transceiver connects
The 4th external-connected port of emitting mould train is connect, the second receiving port Nx RX2 connection first of the first frequency range of RF transceiver receives
First port P of the second switching switch of mould group, the second receiving port Ny RX2 connection of the second frequency range of RF transceiver
Second port P of the second switching switch of the first receiving module, the third receiving port Nx of the first frequency range of RF transceiver
2 T-ports of RX3 and third receiving port Ny RX3 the first receiving port of connection of the second frequency range selection switch, first receives
13rd external-connected port of the port the P connection emitting mould train of port selection switch, the 4th of the first frequency range of RF transceiver connect
2 T-ports of receiving end mouth Nx RX4 and the 4th receiving port Ny RX4 the second receiving port of connection of the second frequency range selection switch,
12nd external-connected port of the port the P connection emitting mould train of the second receiving port selection switch, the port PDET of RF transceiver
Connect the tenth external-connected port of emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of emitting mould train, and 2 of the second antenna sets
Antenna is separately connected 2 ports P of the first switching switch of the first receiving module, and 2 antennas of third antenna group are separately connected
2 ports P of the first switching switch of the second receiving module, 2 antennas of the 4th antenna sets are separately connected third receiving module
First switching switch 2 ports P.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to transmitting signal with first port P, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first port P for controlling second channel selection switch is connected to local terminal third T-port, is sent out
Signal is penetrated, realizes and signal is emitted by the antenna of antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the port third P, and second T-port in first port P and local terminal for controlling second channel selection switch connects
It is logical, emit signal, realizes and signal is emitted by the antenna of antenna sets.
In 4th transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to the port third P, and first T-port in first port P and local terminal for controlling second channel selection switch connects
It is logical, emit signal, realizes and signal is emitted by the antenna of antenna sets.
As shown in Fig. 3 P, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
DL CA is not supported;4. supporting SRS4 days line wheel hairs;5. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules, 4 antenna sets and 2 receptions
Port selection switch (including SPDT switch), wherein each antenna sets include 2 antennas, RF transceiver, the first transmitting mould
Group, the second emitting mould train, the first receiving port selection switch and the second receiving port selection switch are set on mainboard, and first connects
Receipts mould group, the second receiving module are set on subplate, and each emitting mould train and each receiving module are close to connected day
Line is placed.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 M, receiving module
As shown in the receiving module of Fig. 1 L, the AUX of the switching switch of connection second of the first receiving module connects for internal components and connection relationship
Other any 1 AUX is met to support transmission SRS TX signal, the AUX connection of the switching switch of connection second of the second receiving module
In addition any 1 AUX is to support transmission SRS TX signal.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range, the of RF transceiver
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of one frequency range, the second transmitting terminal of the second frequency range
The third external-connected port of mouth Ny TX2 the second emitting mould train of connection, the first receiving port Nx of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of RX1 the first emitting mould train of connection, the second frequency range of RF transceiver connects
Connect the 4th external-connected port of the first emitting mould train, the second receiving port Nx RX2 connection second of the first frequency range of RF transceiver
Second receiving port Ny RX2 connection second of the second external-connected port of emitting mould train, the second frequency range of RF transceiver emits mould
4th external-connected port of group, the third receiving port Nx RX3 of the first frequency range of RF transceiver and the third of the second frequency range receive
2 T-ports of port Ny RX3 the first receiving port of connection selection switch, the port the P connection of the first receiving port selection switch
12nd external-connected port of the second emitting mould train, the frequency of the 4th receiving port Nx RX4 of the first frequency range of RF transceiver and second
2 T-ports of the 4th receiving port Ny RX4 the second receiving port of connection selection switch of section, the second receiving port selection switch
The port P connect the first emitting mould train the 12nd external-connected port, RF transceiver the first port PDET1 connection first transmitting
Tenth external-connected port of mould group, the 2nd port PDET2 of RF transceiver connect the tenth external-connected port of the second emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas be separately connected the 5th the 6th external-connected port of the second emitting mould train, 2 antennas of third antenna group are separately connected
2 ports P of the first switching switch of one receiving module, 2 antennas of the 4th antenna sets are separately connected the second receiving module
2 ports P of the first switching switch.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T of the first passage selection switch of the first emitting mould train
Port is connected to first port P, emits signal, meanwhile, the first of the first passage selection switch of the first emitting mould train of control
A T-port is connected to the port third P, and controls first T-port and first port P company that second channel selection switchs
It is logical, emit signal, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T of the first passage selection switch of the second emitting mould train
Port is connected to first port P, emits signal, meanwhile, the first of the first passage selection switch of the second emitting mould train of control
A T-port is connected to the port third P, and controls first T-port and first port P company that second channel selection switchs
It is logical, emit signal, realizes and signal is emitted by the antenna of antenna sets.
As shown in Fig. 3 Q, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
DL CA is not supported;4. supporting SRS4 days line wheel hairs;5. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules, 4 antenna sets and 1 reception
Port selection switch (including SPDT switch), wherein each antenna sets include 2 antennas, RF transceiver, the first transmitting mould
Group, the second emitting mould train, the first receiving module and receiving port selection switch are set on mainboard, and the second receiving module is set to
On subplate, and each emitting mould train and each receiving module are close to connected antenna and place.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 M, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 L, and the of AUX the second emitting mould train of connection of the first receiving module
Seven external-connected ports emit signal to support to emit by respective antenna SRS TX signal or autonomous switching antenna, and second receives mould
Other any 1 AUX of AUX connection of the switching switch of connection second of group is to support transmission SRS TX signal.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range, the of RF transceiver
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of one frequency range, the second transmitting terminal of the second frequency range
The third external-connected port of mouth Ny TX2 the second emitting mould train of connection, the first receiving port Nx of the first frequency range of RF transceiver
First receiving port Ny RX1 of the second external-connected port of RX1 the first emitting mould train of connection, the second frequency range of RF transceiver connects
Connect the 4th external-connected port of the first emitting mould train, the second receiving port Nx RX2 connection second of the first frequency range of RF transceiver
Second receiving port Ny RX2 connection second of the second external-connected port of emitting mould train, the second frequency range of RF transceiver emits mould
4th external-connected port of group, the of third receiving port Nx RX3 the first receiving module of connection of the first frequency range of RF transceiver
First port P of two switching switches, the third receiving port Ny RX3 connection first of the second frequency range of RF transceiver receive
Second port P of the second switching switch of mould group, the 4th receiving port Nx RX4 of the first frequency range of RF transceiver and the
2 T-ports of the 4th receiving port Ny RX4 connection receiving port selection switch of two frequency ranges, the P of receiving port selection switch
Port connects the 12nd external-connected port of the first emitting mould train, the first port PDET1 connection the first transmitting mould of RF transceiver
Tenth external-connected port of group, the 2nd port PDET2 of RF transceiver connect the tenth external-connected port of the second emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas be separately connected the 5th the 6th external-connected port of the second emitting mould train, 2 antennas of third antenna group are separately connected
2 ports P of the first switching switch of one receiving module, 2 antennas of the 4th antenna sets are separately connected the second receiving module
2 ports P of the first switching switch.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T of the first passage selection switch of the first emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the first emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T of the first passage selection switch of the second emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the second emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
It realizes and signal is emitted by the antenna of antenna sets.
As shown in Fig. 3 R, which supports following functions: 1. 5G NR two-band;2. supporting DL CA;3. propping up
Hold 4 antenna SRS switching;4. NR 1T4R (totally 1 tunnel emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein are penetrated
Frequency transceiver, emitting mould train, the first receiving module and the second receiving module are set on mainboard (in respective figure 3 on the upside of battery
A mould group), third receiving module is set on subplate (1 mould group on the downside of battery in respective figure), and each receiving module is equal
It is placed close to the antenna connected.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, as shown in figure 2m, each receiving module is such as Fig. 1 L for the internal components structure of emitting mould train and connection relationship
Shown in receiving module.The 9th of the AUX connection emitting mould train of the connection switching switch of local terminal first of first receiving module is external
Port emits signal to support to emit by respective antenna SRS TX signal or autonomous switching antenna, the second receiving module
The 8th external-connected port of the AUX connection emitting mould train of the switching switch of local terminal first is connected to support to emit SRS by respective antenna
TX signal or autonomous switching antenna emit signal, and a port P of the second switching switch of third receiving module, which connects, to be sent
The third T-port of 7th external-connected port of mould group, the second switching switch of third receiving module connects an AUX, which connects
Another AUX is met to support transmission SRS TX signal.
First external-connected port of the first emission port Nx TX1 connection emitting mould train of the first frequency range of RF transceiver, is penetrated
The third external-connected port of first emission port Ny TX1 connection emitting mould train of the second frequency range of frequency transceiver, RF transceiver
Second external-connected port of the first receiving port Nx RX1 connection emitting mould train of the first frequency range, the second frequency range of RF transceiver
The first receiving port Ny RX1 connection emitting mould train the 4th external-connected port, RF transceiver the port PDET connection transmitting mould
Tenth external-connected port of group, the tenth of the 4th receiving port Nx RX4 connection emitting mould train of the first frequency range of RF transceiver the
Two external-connected ports, the second switching of the 4th receiving port Ny RX4 connection third receiving module of the second frequency range of RF transceiver
Another port P of switch, third receiving port Ny RX3 the second receiving module of connection of the second frequency range of RF transceiver
One port P of the second switching switch, the third receiving port Nx RX3 connection second of the first frequency range of RF transceiver receive
Another port P of second switching switch of mould group, the second receiving port Ny RX2 connection of the second frequency range of RF transceiver
One port P of the second switching switch of the first receiving module, the second receiving port Nx of the first frequency range of RF transceiver
Another port P of second switching switch of RX2 the first receiving module of connection.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of emitting mould train, and 2 of the second antenna sets
Antenna connects 2 ports P of the first switching switch of the first receiving module, and 2 antennas connection second of third antenna group receives
2 ports P of the first switching switch of mould group.First switching of 2 antennas connection third receiving module of the 4th antenna sets is opened
2 ports P closed.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to first port P, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to the port third P, is realized logical
Cross the antenna transmitting signal of antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to second port P, is realized logical
Cross the antenna transmitting signal of antenna sets.
In 4th transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P, is realized logical
The antenna transmitting signal of antenna sets is crossed, to support the channel quality of the Nx antenna of the 4th antenna sets of base station sounds.
As shown in Fig. 3 S, which supports following functions: 1. 5G NR two-band;2. supporting DL CA;3. propping up
Hold 4 antenna SRS switching;4. NR 1T4R (totally 1 tunnel emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein are penetrated
Frequency transceiver, emitting mould train and the first receiving module are set on mainboard (2 mould groups on the upside of battery in respective figure), and second connects
It receives mould group and third receiving module is set on subplate (1 mould group on the downside of battery in respective figure), and each receiving module is equal
It is placed close to the antenna connected.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, as shown in figure 2m, each receiving module is such as Fig. 1 L for the internal components structure of emitting mould train and connection relationship
Shown in receiving module.The 9th of the aux port connection emitting mould train of the connection switching switch of local terminal first of first receiving module
External-connected port emits signal to support to emit by respective antenna SRS TX signal or autonomous switching antenna.Second receiving module
Second switching switch a port P connection sending module the 8th external-connected port, the second receiving module second switching opens
The third T-port of pass connects an AUX, which connects another AUX to support transmission SRS TX signal.Third receiving module
Second switching switch a port P connection sending module the 7th external-connected port, third receiving module second switching opens
The third T-port of pass connects an AUX, which connects another AUX to support transmission SRS TX signal.
First external-connected port of the first emission port Nx TX1 connection emitting mould train of the first frequency range of RF transceiver, is penetrated
The third external-connected port of first emission port Ny TX1 connection emitting mould train of the second frequency range of frequency transceiver, RF transceiver
Second external-connected port of the first receiving port Nx RX1 connection emitting mould train of the first frequency range, the second frequency range of RF transceiver
The first receiving port Ny RX1 connection emitting mould train the 4th external-connected port, RF transceiver the port PDET connection transmitting mould
Tenth external-connected port of group, the tenth of the 4th receiving port Nx RX4 connection emitting mould train of the first frequency range of RF transceiver the
Two external-connected ports, the second switching of the 4th receiving port Ny RX4 connection third receiving module of the second frequency range of RF transceiver
Another port P of switch, the tenth of the third receiving port Ny RX3 connection emitting mould train of the second frequency range of RF transceiver the
Three external-connected ports, the second switching of third receiving port Nx RX3 the second receiving module of connection of the first frequency range of RF transceiver
Another port P of switch, third receiving port Ny RX2 the first receiving module of connection of the second frequency range of RF transceiver
One port P of the second switching switch, the third receiving port Nx RX2 connection first of the first frequency range of RF transceiver receive
Another port P of second switching switch of mould group.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of emitting mould train, and 2 of the second antenna sets
Antenna connects 2 ports P of the first switching switch of the first receiving module, and 2 antennas connection second of third antenna group receives
2 ports P of the first switching switch of mould group.First switching of 2 antennas connection third receiving module of the 4th antenna sets is opened
2 ports P closed.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to first port P, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to the port third P, is realized logical
Cross the antenna transmitting signal of antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to second port P, is realized logical
Cross the antenna transmitting signal of antenna sets.
In 4th transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P, is realized logical
The antenna transmitting signal of antenna sets is crossed, to support the channel quality of the Nx antenna of the 4th antenna sets of base station sounds.
As shown in Fig. 3 T, which supports following functions: 1. 5G NR two-band;2. supporting DL CA;3. propping up
Hold 4 antenna SRS switching;4. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules and 4 antenna sets, wherein are penetrated
Frequency transceiver, the first emitting mould train and the second emitting mould train are set on mainboard (2 mould groups on the upside of battery in respective figure), the
One receiving module and the second receiving module are set on subplate (2 mould groups on the downside of battery in respective figure), and each reception mould
Group is close to connected antenna and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, as shown in figure 2m, each receiving module is such as Fig. 1 L for the internal components structure of emitting mould train and connection relationship
Shown in receiving module.One port P of the second switching switch of the second receiving module connects outside the 7th of the first sending module
Connect port, the third T-port of the second switching switch of the second receiving module connects an AUX, the AUX connect another AUX with
Support transmission SRS TX signal.One port P of the second switching switch of the first receiving module connects the of the second sending module
The third T-port of seven external-connected ports, the second switching switch of the first receiving module connects an AUX, which connects another
AUX is to support transmission SRS TX signal.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range of RF transceiver is penetrated
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of the first frequency range of frequency transceiver, radio-frequency receiving-transmitting
The third external-connected port of second emission port Ny TX2 the second emitting mould train of connection of the second frequency range of device, the of RF transceiver
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection of one frequency range, the second frequency range of RF transceiver
First receiving port Ny RX1 the first emitting mould train of connection the 4th external-connected port, the second of the first frequency range of RF transceiver
Second external-connected port of receiving port Nx RX2 the second emitting mould train of connection, the second receiving end of the second frequency range of RF transceiver
4th external-connected port of mouth Ny RX2 the second emitting mould train of connection, the third receiving port Nx of the first frequency range of RF transceiver
12nd external-connected port of RX3 the second emitting mould train of connection, the third receiving port Ny RX3 of the second frequency range of RF transceiver
Connect a port P of the second switching switch of the first receiving module, the 4th receiving port of the second frequency range of RF transceiver
One port P of the second switching switch of Ny RX4 the second receiving module of connection, the 4th of the first frequency range of RF transceiver connect
12nd external-connected port of receiving end mouth Nx RX4 the first emitting mould train of connection, the first hair of the port PDET1 connection of RF transceiver
The tenth external-connected port of mould group is penetrated, the port PDET2 of RF transceiver connects the tenth external-connected port of the second emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas connect the second emitting mould train the 5th the 6th external-connected port, third antenna group 2 antennas connection first receive mould
2 ports P of the first switching switch of group, 2 antennas of the 4th antenna sets connect the first switching switch of the second receiving module
2 ports P.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T of the first passage selection switch of the first emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the first emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T of the first passage selection switch of the second emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the second emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
As shown in Fig. 3 U, which supports following functions: 1. 5G NR two-band;2. supporting DL CA;3. propping up
Hold 4 antenna SRS switching;4. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules and 4 antenna sets, wherein are penetrated
Frequency transceiver, the first emitting mould train, the second emitting mould train and the first receiving module are set on mainboard (in respective figure on battery
The mould group of side 3), the second receiving module is set on subplate (1 mould group on the downside of battery in respective figure), and each receiving module
Connected antenna is close to place.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, as shown in figure 2m, each receiving module is such as Fig. 1 L for the internal components structure of emitting mould train and connection relationship
Shown in receiving module.One port P of the second switching switch of the second receiving module connects outside the 7th of the first sending module
Connect port, the third T-port of the second switching switch of the second receiving module connects an AUX, the AUX connect another AUX with
Support transmission SRS TX signal.The aux port connection emitting mould train of the connection switching switch of local terminal first of first receiving module
7th external-connected port emits signal to support to emit by respective antenna SRS TX signal or autonomous switching antenna.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range of RF transceiver is penetrated
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of the first frequency range of frequency transceiver, radio-frequency receiving-transmitting
The third external-connected port of second emission port Ny TX2 the second emitting mould train of connection of the second frequency range of device, the of RF transceiver
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection of one frequency range, the second frequency range of RF transceiver
First receiving port Ny RX1 the first emitting mould train of connection the 4th external-connected port, the second of the first frequency range of RF transceiver
Second external-connected port of receiving port Nx RX2 the second emitting mould train of connection, the second receiving end of the second frequency range of RF transceiver
4th external-connected port of mouth Ny RX2 the second emitting mould train of connection, the third receiving port Nx of the first frequency range of RF transceiver
12nd external-connected port of RX3 the second emitting mould train of connection, the third receiving port Ny RX3 of the second frequency range of RF transceiver
Connect a port P of the second switching switch of the first receiving module, the 4th receiving port of the second frequency range of RF transceiver
One port P of the second switching switch of Ny RX4 the second receiving module of connection, the 4th of the first frequency range of RF transceiver connect
12nd external-connected port of receiving end mouth Nx RX4 the first emitting mould train of connection, the first hair of the port PDET1 connection of RF transceiver
The tenth external-connected port of mould group is penetrated, the port PDET2 of RF transceiver connects the tenth external-connected port of the second emitting mould train.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas connect the second emitting mould train the 5th the 6th external-connected port, third antenna group 2 antennas connection first receive mould
2 ports P of the first switching switch of group, 2 antennas of the 4th antenna sets connect the first switching switch of the second receiving module
2 ports P.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T of the first passage selection switch of the first emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the first emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T of the first passage selection switch of the second emitting mould train
Port is connected to first port P, emits signal, while first that the first passage selection for controlling the second emitting mould train switchs
T-port is connected to the port third P, and first T-port for controlling second channel selection switch is connected to first port P,
Emit signal, realizes and signal is emitted by the antenna of antenna sets.
As shown in Fig. 3 V, which supports following functions: 1. 5G NR two-band;2. not supporting DL CA;③
4 antenna SRS are not supported to emit poll;4. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules, 4 antenna sets and 1 reception
Port selection switch (including SPDT switch), wherein RF transceiver, emitting mould train, the first receiving module, second receive mould
Group and receiving port selection switch are set on mainboard (3 mould groups on the upside of battery in respective figure), the setting of third receiving module
In (1 mould group on the downside of battery in respective figure) on subplate, and each receiving module is close to connected antenna and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 J, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 M.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range, the of RF transceiver
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of one frequency range, the second transmitting terminal of the second frequency range
The third external-connected port of mouth Ny TX2 the second emitting mould train of connection, the 8th of the port the PDET connection emitting mould train of RF transceiver the
External-connected port, the 4th receiving port Nx RX4 of the first frequency range of RF transceiver and the 4th receiving port Ny of the second frequency range
The port P of 2 T-ports of RX4 connection receiving port selection switch, receiving port selection switch connects the of the first emitting mould train
Ten external-connected ports, the second switching of third receiving port Nx RX3 the second receiving module of connection of the first frequency range of RF transceiver
One port P of switch, the of third receiving port Ny RX3 the second receiving module of connection of the second frequency range of RF transceiver
Another port P of two switching switches, the second receiving port Nx RX2 connection first of the first frequency range of RF transceiver receive
One port P of the second switching switch of mould group, the second receiving port Ny RX2 connection of the second frequency range of RF transceiver the
Another port P of second switching switch of one receiving module.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of emitting mould train, and 2 of the second antenna sets
Antenna connects 2 ports P of the first switching switch of the first receiving module, and 2 antennas connection second of third antenna group receives
First switching of 2 ports P of the first switching switch of mould group, 2 antennas connection third receiving module of the 4th antenna sets is opened
2 ports P closed.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
One port P connection, realizes and emits signal by an antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
Two port P connections, realize and emit signal by another antenna of first antenna group.
In third transmit cycle, first T-port that electronic equipment controls the channel selection switch of emitting mould train is kept
It is connected to the port third P, the bypass channel conducting of control third receiving module, and controls the first of third receiving module and cut
The third T-port for changing switch is connected to a port P of the first switching switch, is realized and is sent out by an antenna of the 4th antenna sets
Penetrate signal.
In 4th transmit cycle, first T-port that electronic equipment controls the channel selection switch of emitting mould train is kept
It is connected to the port third P, the bypass channel conducting of control third receiving module, and controls the first of third receiving module and cut
The third T-port for changing switch is connected to another port P of the first switching switch, realizes another Zhi Tian for passing through the 4th antenna sets
Line emits signal.
As shown in Fig. 3 W, which supports following functions: 1. 5G NR two-band;2. not supporting DL CA;③
4 antenna SRS are not supported to emit poll;4. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules, 4 antenna sets and 2 receptions
Port selection switch (including SPDT switch), wherein RF transceiver, emitting mould train, the first receiving module and 2 receiving ends
Mouth selection switch is set on mainboard (2 mould groups on the upside of battery in respective figure), the second receiving module and third receiving module
(2 mould groups on the downside of battery in respective figure) are set on subplate, and each receiving module is close to connected antenna and puts
It sets.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 J, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 M.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range, the of RF transceiver
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of one frequency range, the second transmitting terminal of the second frequency range
The third external-connected port of mouth Ny TX2 the second emitting mould train of connection, the 8th of the port the PDET connection emitting mould train of RF transceiver the
External-connected port, the 4th receiving port Nx RX4 of the first frequency range of RF transceiver and the 4th receiving port Ny of the second frequency range
2 T-ports of RX4 the first receiving port of connection selection switch, the first hair of the port P connection of the first receiving port selection switch
Penetrate the tenth external-connected port of mould group, the 4th of the 4th receiving port Nx RX4 of the first frequency range of RF transceiver and the second frequency range the
2 T-ports of receiving port Ny RX4 the first receiving port of connection selection switch, the port P of the first receiving port selection switch
Connect a port P of the second switching switch of the second receiving module, the second receiving port of the first frequency range of RF transceiver
One port P of the second switching switch of Nx RX2 the first receiving module of connection, the second of the second frequency range of RF transceiver connect
Another port P of second switching switch of receiving end mouth Ny RX2 the first receiving module of connection.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of emitting mould train, and 2 of the second antenna sets
Antenna connects 2 ports P of the first switching switch of the first receiving module, and 2 antennas connection second of third antenna group receives
First switching of 2 ports P of the first switching switch of mould group, 2 antennas connection third receiving module of the 4th antenna sets is opened
2 ports P closed.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
One port P connection, realizes and emits signal by an antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
Two port P connections, realize and emit signal by another antenna of first antenna group.
In third transmit cycle, first T-port that electronic equipment controls the channel selection switch of emitting mould train is kept
It is connected to the port third P, the bypass channel conducting of control third receiving module, and controls the first of third receiving module and cut
The third T-port for changing switch is connected to a port P of the first switching switch, is realized and is sent out by an antenna of the 4th antenna sets
Penetrate signal.
In 4th transmit cycle, first T-port that electronic equipment controls the channel selection switch of emitting mould train is kept
It is connected to the port third P, the bypass channel conducting of control third receiving module, and controls the first of third receiving module and cut
The third T-port for changing switch is connected to another port P of the first switching switch, realizes another Zhi Tian for passing through the 4th antenna sets
Line emits signal.
As shown in Fig. 3 X, which supports following functions: 1. 5G NR two-band;2. not supporting DL CA;③
4 antenna SRS are not supported to emit poll;4. NR 2T4R (2 tunnel of one-segment emits 8 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules, 4 antenna sets and 2 receptions
Port selection switch (including SPDT switch), wherein RF transceiver, the first emitting mould train, the second emitting mould train and 2 connect
It receives port selection switch and is set on mainboard (2 mould groups on the upside of battery in respective figure), the first receiving module and second receives
Mould group is set on subplate (2 mould groups on the downside of battery in respective figure), and each receiving module is close to connected antenna
It places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 J, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 M.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range of RF transceiver is penetrated
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of the first frequency range of frequency transceiver, radio-frequency receiving-transmitting
The third external-connected port of second emission port Ny TX2 the second emitting mould train of connection of the second frequency range of device, the of RF transceiver
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection of one frequency range, the second frequency range of RF transceiver
First receiving port Ny RX1 the first emitting mould train of connection the 4th external-connected port, the second of the first frequency range of RF transceiver
Second external-connected port of receiving port Nx RX2 the second emitting mould train of connection, the second receiving end of the second frequency range of RF transceiver
The port PDET1 of 4th external-connected port of mouth Ny RX2 the second emitting mould train of connection, RF transceiver connects the first emitting mould train
The 8th external-connected port, the port PDET2 of RF transceiver connects the 8th external-connected port of the second emitting mould train, RF transceiver
The first frequency range the 4th receiving port Nx RX4 and the second frequency range the 4th receiving port Ny RX4 the first receiving port of connection
2 T-ports of switch are selected, the port P of the first receiving port selection switch connects the tenth external-connected port of the first emitting mould train,
The third receiving port Nx RX3 of first frequency range of RF transceiver and the third receiving port Ny RX3 connection of the second frequency range
The port P of 2 T-ports of two receiving ports selection switch, the second receiving port selection switch connects the of the second emitting mould train
Ten external-connected ports.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas be separately connected the 5th the 6th external-connected port of the second emitting mould train, 2 antennas connection first of third antenna group connects
2 ports P of the first switching switch of mould group are received, 2 antennas of the 4th antenna sets connect the first switching of the second receiving module
2 ports P of switch.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P or second port P, emits signal, while controlling the channel selection switch of the first emitting mould train
First T-port holding is connected to the port third P, and controls the bypass channel conducting of the second receiving module, emits signal, real
Signal is now emitted by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P or second port P, emits signal, while controlling the channel selection switch of the first emitting mould train
First T-port holding is connected to the port third P, and controls the bypass channel conducting of the second receiving module, emits signal, real
Signal is now emitted by the antenna of the second antenna sets.
As shown in Fig. 3 Y, which supports following functions: 1. 5G NR two-band;2. not supporting DL CA;③
4 antenna SRS are not supported to emit poll;4. NR 2T4R (2 tunnel of one-segment emits 8 tunnels and receives).
The 5G radio architectures include that RF transceiver, 2 emitting mould trains, 2 receiving modules, 4 antenna sets and 12 connect
It receives port selection switch (including SPDT switch), wherein RF transceiver, the first emitting mould train, the second emitting mould train, first connect
It receives mould group and receiving port selection switch is set on mainboard (3 mould groups on the upside of battery in respective figure), the second receiving module
(2 mould groups on the downside of battery in respective figure) are set on subplate, and each receiving module is close to connected antenna and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 J, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 M.
First external connection end of first emission port Nx TX1 the first emitting mould train of connection of the first frequency range of RF transceiver
Mouthful, the third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of the second frequency range of RF transceiver is penetrated
First external-connected port of second emission port Nx TX2 the second emitting mould train of connection of the first frequency range of frequency transceiver, radio-frequency receiving-transmitting
The third external-connected port of second emission port Ny TX2 the second emitting mould train of connection of the second frequency range of device, the of RF transceiver
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection of one frequency range, the second frequency range of RF transceiver
First receiving port Ny RX1 the first emitting mould train of connection the 4th external-connected port, the second of the first frequency range of RF transceiver
Second external-connected port of receiving port Nx RX2 the second emitting mould train of connection, the second receiving end of the second frequency range of RF transceiver
The port PDET1 of 4th external-connected port of mouth Ny RX2 the second emitting mould train of connection, RF transceiver connects the first emitting mould train
The 8th external-connected port, the port PDET2 of RF transceiver connects the 8th external-connected port of the second emitting mould train, RF transceiver
The first frequency range the 4th receiving port Nx RX4 and the second frequency range the 4th receiving port Ny RX4 the first receiving port of connection
2 T-ports of switch are selected, the port P of the first receiving port selection switch connects the tenth external-connected port of the first emitting mould train,
One of second switching switch of third receiving port Nx RX3 the first receiving module of connection of the first frequency range of RF transceiver
The port P, the second switching switch of third receiving port Ny RX3 the first receiving module of connection of the second frequency range of RF transceiver
Another port P.
2 antennas of first antenna group are separately connected the 5th the 6th external-connected port of the first emitting mould train, the second antenna sets
2 antennas be separately connected the 5th the 6th external-connected port of the second emitting mould train, 2 antennas connection first of third antenna group connects
2 ports P of the first switching switch of mould group are received, 2 antennas of the 4th antenna sets connect the first switching of the second receiving module
2 ports P of switch.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P or second port P, emits signal, while controlling the channel selection switch of the second emitting mould train
First T-port holding is connected to the port third P, and controls the bypass channel conducting of the first receiving module, emits signal, real
Signal is now emitted by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P or second port P, emits signal, while controlling the channel selection switch of the first emitting mould train
First T-port holding is connected to the port third P, and controls the bypass channel conducting of the second receiving module, emits signal, real
Signal is now emitted by the antenna of the second antenna sets.
As shown in Fig. 3 Z, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
Support DL CA;4. 4 antenna SRS is not supported to emit poll;5. NR1T4R (1 tunnel of two-band emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein the
One antenna sets include 2 antennas, and the second antenna sets include 2 antennas, and third antenna group includes 2 antennas, the 4th antenna sets packet
2 antennas are included, RF transceiver, emitting mould train, the first, second receiving module are set on mainboard (in respective figure on battery
The mould group of side 3), third receiving module is set on subplate (1 mould group on the downside of battery in respective figure), and each emitting mould train
Or receiving module is close to connected antenna sets and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 J, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 M.
First external-connected port of the emission port Nx TX connection emitting mould train of the frequency range Nx of RF transceiver, frequency range Ny's
The third external-connected port of emission port Ny TX connection emitting mould train, the first receiving port Nx of the frequency range Nx of RF transceiver
Second external-connected port of RX1 connection emitting mould train, the first receiving port Ny RX1 connection transmitting of the frequency range Ny of RF transceiver
4th external-connected port of mould group, the 8th external-connected port of the power sensor port PDET connection emitting mould train of RF transceiver, is penetrated
Tenth external-connected port of the 4th receiving port Nx RX4 connection emitting mould train of the frequency range Nx of frequency transceiver, the frequency of RF transceiver
Second T-port of the second switching switch of the 4th receiving port Ny RX4 connection third receiving module of section Ny, RF transceiver
Frequency range Ny third receiving port Ny RX3 the second receiving module of connection second switching switch the second T-port, radio frequency receive
The first T-port for sending out the second switching switch of third receiving port Nx RX3 the second receiving module of connection of the frequency range Nx of device, is penetrated
2nd end T of the second switching switch of second receiving port Ny RX2 the first receiving module of connection of the frequency range Ny of frequency transceiver
Mouthful, the first of the second switching switch of second receiving port Nx RX2 the first receiving module of connection of the frequency range Nx of RF transceiver
T-port.
The 5th external-connected port and the 6th external-connected port of 2 antennas connection emitting mould train of first antenna group, emitting mould train
The 7th external-connected port connection third receiving module the second switching switch the first T-port, 2 antennas of the second antenna sets connect
2 T-ports of the first switching switch of the first receiving module are connect, 2 antennas of third antenna group connect the second receiving module
2 T-ports of the first switching switch, 2 of the first switching switch of 2 antennas connection third receiving module of the 4th antenna sets
T-port.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
One port P connection, realizes and emits signal by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
Three port P connections, and the bypass channel conducting of mould group is controlled and received, it realizes and is emitted by first antenna of the 4th antenna sets
Signal.
If Fig. 4 A shows, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;3. propping up
Hold DL CA;4. 4 antenna SRS is not supported to emit poll;5. NR1T4R (1 tunnel of two-band emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein the
One antenna sets include 2 antennas, and the second antenna sets include 2 antennas, and third antenna group includes 2 antennas, the 4th antenna sets packet
2 antennas are included, RF transceiver, emitting mould train, the first receiving module are set on mainboard (in respective figure 2 on the upside of battery
Mould group), second, third receiving module is set on subplate (2 mould groups on the downside of battery in respective figure), and each emitting mould train
Or receiving module is close to connected antenna sets and places.For the disposing way of emitting mould train and receiving module, the application
It does not limit, for example, emitting mould train or receiving module level can be put, it can also be vertical by emitting mould train or receiving module
It puts.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 J, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 M.
First external-connected port of the emission port Nx TX connection emitting mould train of the frequency range Nx of RF transceiver, frequency range Ny's
The third external-connected port of emission port Ny TX connection emitting mould train, the first receiving port Nx of the frequency range Nx of RF transceiver
Second external-connected port of RX1 connection emitting mould train, the first receiving port Ny RX1 connection transmitting of the frequency range Ny of RF transceiver
4th external-connected port of mould group, the 8th external-connected port of the power sensor port PDET connection emitting mould train of RF transceiver, is penetrated
Tenth external-connected port of the 4th receiving port Nx RX4 connection emitting mould train of the frequency range Nx of frequency transceiver, the frequency of RF transceiver
Second T-port of the second switching switch of the 4th receiving port Ny RX4 connection third receiving module of section Ny, RF transceiver
Frequency range Ny third receiving port Ny RX3 the second receiving module of connection second switching switch the second T-port, radio frequency receive
The first T-port for sending out the second switching switch of third receiving port Nx RX3 the second receiving module of connection of the frequency range Nx of device, is penetrated
2nd end T of the second switching switch of second receiving port Ny RX2 the first receiving module of connection of the frequency range Ny of frequency transceiver
Mouthful, the first of the second switching switch of second receiving port Nx RX2 the first receiving module of connection of the frequency range Nx of RF transceiver
T-port.
The 5th external-connected port and the 6th external-connected port of 2 antennas connection emitting mould train of first antenna group, emitting mould train
The 7th external-connected port connection third receiving module the second switching switch the first T-port, 2 antennas of the second antenna sets connect
2 T-ports of the first switching switch of the first receiving module are connect, 2 antennas of third antenna group connect the second receiving module
2 T-ports of the first switching switch, 2 of the first switching switch of 2 antennas connection third receiving module of the 4th antenna sets
T-port.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
One port P connection, realizes and emits signal by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
Three port P connections, and the bypass channel conducting of mould group is controlled and received, it realizes and is emitted by first antenna of the 4th antenna sets
Signal.
As shown in Figure 4 B, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
Support DL CA;4. 4 antenna SRS is not supported to emit poll;5. NR2T4R (2 tunnel of two-band emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules and 4 antenna sets, wherein the
One antenna sets include 2 antennas, and the second antenna sets include 2 antennas, and third antenna group includes 2 antennas, the 4th antenna sets packet
2 antennas are included, RF transceiver, the first and second emitting mould train are set on mainboard (2 mould groups on the upside of battery in respective figure),
First, second receiving module is set on subplate (2 mould groups on the downside of battery in respective figure), and each emitting mould train or reception
Mould group is close to connected antenna sets and places.For the disposing way of emitting mould train and receiving module, the application is simultaneously unlimited
It is fixed, for example, emitting mould train or receiving module level can be put, it can also be by emitting mould train or receiving module vertical display.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 J, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 M.
First external-connected port of first emission port Nx TX1 the first emitting mould train of connection of the frequency range Nx of RF transceiver,
The third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of frequency range Ny, the frequency range Nx's of RF transceiver
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection, the first of the frequency range Ny of RF transceiver receive
4th external-connected port of port Ny RX1 the first emitting mould train of connection, the second emission port Nx of the frequency range Nx of RF transceiver
First external-connected port of TX2 the second emitting mould train of connection, second emission port Ny TX2 the second emitting mould train of connection of frequency range Ny
Third external-connected port, the second of second receiving port Nx RX2 the second emitting mould train of connection of the frequency range Nx of RF transceiver
External-connected port, the 4th external connection end of second receiving port Ny RX2 the second emitting mould train of connection of the frequency range Ny of RF transceiver
Mouthful, the 8th external-connected port of first power sensor port PDET1 the first emitting mould train of connection of RF transceiver, RF transceiver
Second power sensor port PDET2 the second emitting mould train of connection the 8th external-connected port, the of the frequency range Nx of RF transceiver
The third of tenth external-connected port of four receiving port Nx RX4 the first emitting mould trains of connection, the frequency range Nx of RF transceiver receives
Tenth external-connected port of port Nx RX3 the second emitting mould train of connection, the 4th receiving port Ny of the frequency range Ny of RF transceiver
Second T-port of the second switching switch of RX4 the second receiving module of connection, the third receiving port of the frequency range Ny of RF transceiver
Second T-port of the second switching switch of Ny RX3 the first receiving module of connection.
The 5th external-connected port and the 6th external-connected port of 2 antennas the first emitting mould train of connection of first antenna group, first
First T-port of the second switching switch of the 7th external-connected port the second receiving module of connection of emitting mould train, the 2 of the second antenna sets
A antenna connects the 5th external-connected port and the 6th external-connected port of the second emitting mould train, the 7th external-connected port of the second emitting mould train
The first T-port of the second switching switch of the first receiving module is connected, 2 antennas of third antenna group connect the first receiving module
The first switching switch 2 T-ports, 2 antennas of the 4th antenna sets connect the 2 of the first switching switch of the second receiving module
A T-port.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
Be connected to first port P, emit signal, while control the first emitting mould train channel selection switch first T-port with
The connection of the port third P, and the bypass channel conducting of mould group is controlled and received, emit signal, realizes the day by first antenna group
Line emits signal.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
Be connected to first port P, emit signal, while control the second emitting mould train channel selection switch first T-port with
The connection of the port third P, and the bypass channel conducting of mould group is controlled and received, emit signal, realizes the day for passing through the second antenna sets
Line emits signal.
As shown in Figure 4 C, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
Support DL CA;4. 4 antenna SRS is not supported to emit poll;5. NR2T4R (2 tunnel of two-band emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules and 4 antenna sets, wherein the
One antenna sets include 2 antennas, and the second antenna sets include 2 antennas, and third antenna group includes 2 antennas, the 4th antenna sets packet
Include 2 antennas, RF transceiver, the first and second emitting mould train, the first receiving module are set on mainboard (battery in respective figure
The mould group of upside 3), the second receiving module is set on subplate (1 mould group on the downside of battery in respective figure), and each transmitting mould
Group or receiving module are close to connected antenna sets and place.For the disposing way of emitting mould train and receiving module, this Shen
It does not limit please, for example, emitting mould train or receiving module level can be put, emitting mould train or receiving module can also be erected
Directly put.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 J, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 M.
First external-connected port of first emission port Nx TX1 the first emitting mould train of connection of the frequency range Nx of RF transceiver,
The third external-connected port of first emission port Ny TX1 the first emitting mould train of connection of frequency range Ny, the frequency range Nx's of RF transceiver
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection, the first of the frequency range Ny of RF transceiver receive
4th external-connected port of port Ny RX1 the first emitting mould train of connection, the second emission port Nx of the frequency range Nx of RF transceiver
First external-connected port of TX2 the second emitting mould train of connection, second emission port Ny TX2 the second emitting mould train of connection of frequency range Ny
Third external-connected port, the second of second receiving port Nx RX2 the second emitting mould train of connection of the frequency range Nx of RF transceiver
External-connected port, the 4th external connection end of second receiving port Ny RX2 the second emitting mould train of connection of the frequency range Ny of RF transceiver
Mouthful, the 8th external-connected port of first power sensor port PDET1 the first emitting mould train of connection of RF transceiver, RF transceiver
Second power sensor port PDET2 the second emitting mould train of connection the 8th external-connected port, the of the frequency range Nx of RF transceiver
The third of tenth external-connected port of four receiving port Nx RX4 the first emitting mould trains of connection, the frequency range Nx of RF transceiver receives
Tenth external-connected port of port Nx RX3 the second emitting mould train of connection, the 4th receiving port Ny of the frequency range Ny of RF transceiver
Second T-port of the second switching switch of RX4 the second receiving module of connection, the third receiving port of the frequency range Ny of RF transceiver
Second T-port of the second switching switch of Ny RX3 the first receiving module of connection.
The 5th external-connected port and the 6th external-connected port of 2 antennas the first emitting mould train of connection of first antenna group, first
First T-port of the second switching switch of the 7th external-connected port the second receiving module of connection of emitting mould train, the 2 of the second antenna sets
A antenna connects the 5th external-connected port and the 6th external-connected port of the second emitting mould train, the 7th external-connected port of the second emitting mould train
The aux port of the first receiving module is connected, 2 antennas of third antenna group connect the first switching switch of the first receiving module
2 T-ports, 2 antennas of the 4th antenna sets connect 2 T-ports of the first switching switch of the second receiving module.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, while controlling first T-port and the end third P of the channel selection switch of the first emitting mould train
Mouth connection, and the bypass channel conducting of mould group is controlled and received, realize that the antenna for passing through first antenna group emits signal.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P, while controlling first T-port and the end third P of the channel selection switch of the second emitting mould train
Mouth connection realizes that first antenna for passing through third antenna group emits signal.
As shown in Figure 4 D, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is supported to emit poll;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein the
One antenna sets include 1 antenna, and the second antenna sets include 1 antenna, and third antenna group includes 1 antenna, the 4th antenna sets packet
1 antenna is included, RF transceiver, the first emitting mould train, the first, second receiving module are set on mainboard (electric in respective figure
3 mould groups on the upside of pond), third receiving module is set on subplate (1 mould group on the downside of battery in respective figure), and each transmitting
Mould group or receiving module are close to connected antenna sets and place.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 L, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 O2.
First external-connected port of the emission port Nx TX connection emitting mould train of the frequency range Nx of RF transceiver, frequency range Nx's
Second external-connected port of the first receiving port Nx RX1 connection emitting mould train, the PDET1 connection of RF transceiver power sensor port
8th external-connected port of emitting mould train, second receiving port Nx RX2 the first receiving module of connection of the frequency range Nx of RF transceiver
Second switching switch the port P, third receiving port Nx RX3 the second receiving module of connection of the frequency range Nx of RF transceiver
Second switching switch the first T-port, the 4th receiving port Nx RX4 connection emitting mould train of the frequency range Nx of RF transceiver
The tenth external-connected port.
4th external-connected port of the antenna connection emitting mould train of first antenna group, 1 antenna connection the of the second antenna sets
First T-port of the first switching switch of one receiving module, 1 antenna of third antenna group connect the first of the second receiving module
Switch the first T-port of switch, the first T of the first switching switch of 1 antenna connection third receiving module of the 4th antenna sets
4th T-port of port, the switching switch of the first emitting mould train connects the aux port of the first receiving module, the first emitting mould train
Switching switch the second T-port connect the second receiving module aux port, the first emitting mould train switching switch the 3rd T
Port connects the first T-port of the second switching switch of third receiving module.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, realizes and signal is emitted by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to the 4th port P, realizes and signal is emitted by the antenna of the second antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to second port P, realizes and signal is emitted by the antenna of third antenna group.
In 4th transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
Holding is connected to the port third P, and controls and receives the bypass channel conducting of mould group, is realized and is sent out by the antenna of the 4th antenna sets
Penetrate signal.
As shown in Figure 4 E, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is supported to emit poll;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein the
One antenna sets include 1 antenna, and the second antenna sets include 1 antenna, and third antenna group includes 1 antenna, the 4th antenna sets packet
1 antenna is included, RF transceiver, the first emitting mould train, the first receiving module are set on mainboard (in respective figure on the upside of battery
2 mould groups), second, third receiving module is set on subplate (2 mould groups on the downside of battery in respective figure), and each transmitting
Mould group or receiving module are close to connected antenna sets and place.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 L, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 O2.
First external-connected port of the emission port Nx TX connection emitting mould train of the frequency range Nx of RF transceiver, frequency range Nx's
Second external-connected port of the first receiving port Nx RX1 connection emitting mould train, the PDET1 connection of RF transceiver power sensor port
8th external-connected port of emitting mould train, second receiving port Nx RX2 the first receiving module of connection of the frequency range Nx of RF transceiver
The second switching switch the first T-port, the third receiving port NxRX3 connection emitting mould train of the frequency range Nx of RF transceiver the
11 external-connected ports, the tenth external connection end of the 4th receiving port Nx RX4 connection emitting mould train of the frequency range Nx of RF transceiver
Mouthful.
4th external-connected port of the antenna connection emitting mould train of first antenna group, 1 antenna connection the of the second antenna sets
First T-port of the first switching switch of one receiving module, 1 antenna of third antenna group connect the first of the second receiving module
Switch the first T-port of switch, the first T of the first switching switch of 1 antenna connection third receiving module of the 4th antenna sets
4th T-port of port, the switching switch of the first emitting mould train connects the aux port of the first receiving module, the first emitting mould train
Switching switch third T-port connection third receiving module second switching switch T-port, the switching of the first emitting mould train
Second T-port of switch connects the T-port of the second switching switch of the second receiving module.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, realizes and signal is emitted by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to the 4th port P, realizes and signal is emitted by the antenna of the second antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to second port P, and controls and receives the bypass channel conducting of mould group, realized and letter is emitted by the antenna of third antenna group
Number.
In 4th transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
Holding is connected to the port third P, and controls and receives the bypass channel conducting of mould group, is realized and is sent out by the antenna of the 4th antenna sets
Penetrate signal.
As illustrated in figure 4f, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is supported to emit poll;5. NR 2T4R (2 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules and 4 antenna sets, wherein the
One antenna sets include 1 antenna, and the second antenna sets include 1 antenna, and third antenna group includes 1 antenna, the 4th antenna sets packet
Include 1 antenna, RF transceiver, the first, second emitting mould train are set on mainboard (2 moulds on the upside of battery in respective figure
Group), the first, second receiving module is set on subplate (2 mould groups on the downside of battery in respective figure), and each emitting mould train
Or receiving module is close to connected antenna sets and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 L, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 O2.
First external-connected port of first emission port Nx TX1 the first emitting mould train of connection of the frequency range Nx of RF transceiver,
Second external-connected port of first receiving port NxRX1 the first emitting mould train of connection of frequency range Nx, RF transceiver power detection end
8th external-connected port of mouth PDET1 the first emitting mould train of connection, the second emission port Nx TX2 of the frequency range Nx of RF transceiver
The first external-connected port of the second emitting mould train is connected, second receiving port Nx RX2 the second emitting mould train of connection of frequency range Nx
Second external-connected port, the 8th external-connected port of RF transceiver power sensor port PDET2 the second emitting mould train of connection, radio frequency are received
Send out the tenth external-connected port of third receiving port Nx RX3 the second emitting mould train of connection of the frequency range Nx of device, the frequency of RF transceiver
Tenth external interface of the 4th receiving port Nx RX4 the first emitting mould train of connection of section Nx.
The antenna of first antenna group connects the 4th external-connected port of the first emitting mould train, the antenna connection of the second antenna sets the
4th external-connected port of two emitting mould trains, 1 antenna of third antenna group connect the first switching switch of the first receiving module
First T-port, 1 antenna of the 4th antenna sets connect the first T-port of the first switching switch of the second receiving module, the first hair
The third T-port for penetrating the switching switch of mould group connects the first T-port that the second switching of the second receiving module switchs, the first transmitting
4th T-port of the switching switch of mould group connects the tenth Single port of the switching switch of the second transmitting module, the second emitting mould train
Switching switch third T-port connect the first receiving module second switching switch the first T-port.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, realizes and signal is emitted by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to second port P, realizes and signal is emitted by first antenna of the second antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to the 4th port P, and controls the bypass channel conducting of the second receiving module, realized and sent out by the antenna of third antenna group
Penetrate signal.
In 4th transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to the port third P, and controls the bypass channel conducting of third receiving module, realized and sent out by the antenna of the 4th antenna sets
Penetrate signal.
As shown in Figure 4 G, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is supported to emit poll;5. NR 2T4R (2 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 1 receiving module and 3 antenna sets, wherein the
One antenna sets include 1 antenna (first antenna), and the second antenna sets include 2 antennas (the second antenna and third antenna), third
Antenna sets include 1 antenna (the 4th antenna), and RF transceiver, the first, second emitting mould train are set on mainboard (respective figure
2 mould groups on the upside of middle battery), receiving module is set on subplate (2 mould groups on the downside of battery in respective figure).
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is close to the second antenna sets and third
Antenna sets setting, receiving module are arranged close to third antenna group.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 L, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 O2.
First external-connected port of first emission port Nx TX1 the first emitting mould train of connection of the frequency range Nx of RF transceiver,
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection of frequency range Nx, RF transceiver power detection end
8th external-connected port of mouth PDET1 the first emitting mould train of connection, the second emission port Nx TX2 of the frequency range Nx of RF transceiver
The first external-connected port of the second emitting mould train is connected, second receiving port Nx RX2 the second emitting mould train of connection of frequency range Nx
Second external-connected port, the 8th external-connected port of RF transceiver power sensor port PDET2 the second emitting mould train of connection, radio frequency are received
Send out the third port of third receiving port Nx RX3 the second emitting mould train of connection of the frequency range Nx of device, the frequency range Nx of RF transceiver
The 4th receiving port Ny RX4 the first transmitting module of connection the tenth external-connected port.
The antenna of first antenna group connects the 4th external-connected port of the first emitting mould train, the antenna connection of the second antenna sets the
4th external-connected port of two emitting mould trains, 1 antenna of third antenna group connect the 5th external-connected port of the second emitting mould train, the
First T-port of the first switching switch of 1 antenna connection receiving module of four antenna sets, the switching switch of the first emitting mould train
Third T-port connection receiving module second switching switch the first T-port, the first emitting mould train switching switch the 4th
T-port connects the tenth Single port of the switching switch of the second transmitting module.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, while controlling first T-port and the end third P of the channel selection switch of the first emitting mould train
Mouth connection, and the bypass channel conducting of mould group is controlled and received, it realizes through corresponding antenna transmitting signal.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P, while first T-port of the channel selection switch of the first emitting mould train of control and the 4th end P
Mouth connection, the 4th T-port for controlling the channel selection switch of the second transmitting module are connected to the 2nd port P, and realization passes through correspondence
Antenna emit signal.
As shown at figure 4h, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is supported to emit poll;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 2 receiving modules and 3 antenna sets, wherein the
One antenna sets include 2 antennas, and the second third antenna group respectively includes 1 antenna, and RF transceiver, emitting mould train, first receive
Mould group is set on mainboard (the mould group of battery upper left side 1 in respective figure), and the second receiving module is set on subplate (corresponding attached
1 mould group on the downside of battery in figure), and each mould group is close to connected antenna sets and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
Mould group is received to be arranged close to third antenna group group.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 L, receiving module
Internal components and connection relationship as shown in the receiving module of Fig. 1 O2, the AUX connection emitting mould train of the first receiving module the 9th outside
Port is connect to support to emit by respective antenna SRS TX signal or autonomous switching antenna and emit signal.
First external-connected port of the first emission port TX1 connection emitting mould train of RF transceiver, the of RF transceiver
Second external-connected port of the first receiving port Nx RX1 connection emitting mould train of one frequency range, the of the first frequency range of RF transceiver
The third external-connected port of three receiving port Nx RX3 connection emitting mould trains, the 4th receiving port of the first frequency range of RF transceiver
6th external-connected port of Nx RX4 connection emitting mould train, the second receiving port Nx RX2 connection of the first frequency range of RF transceiver
The port P of second switching switch of the first receiving module.The 4th of the port the PDET connection emitting mould train of RF transceiver is external
Port.
Second antenna sets connect the port P of the first switching switch (DP3T switch) of the first receiving module, and the first switching is opened
First T-port closed corresponds to the first auxiliary port of first receiving module, and second T-port of the first switching switch connects
Filter is connect, filter connects LNA, first T-port of the switching switch of LNA connection second (DP2T switch), and the first switching is opened
The third T-port of pass connects the second auxiliary port of the first receiving module, the second auxiliary port connection emitting mould train
8th external-connected port.
4th antenna sets and the second receiving module, the second receiving module internal components connection relationship and aforementioned second antenna sets
Similar with the first receiving module, details are not described herein again.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
One port P connection, meanwhile, first T-port for controlling the channel selection switch of emitting mould train keeps connecting with second port P
It is logical, it realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
Four port P connections, meanwhile, first T-port for controlling the channel selection switch of emitting mould train keeps connecting with the port third P
It is logical, it realizes and signal is emitted by the antenna of antenna sets.
As shown in fig. 41, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is supported to emit poll;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 2 receiving modules and 3 antenna sets, wherein the
One antenna sets include 2 antennas, and the second third antenna group respectively includes 1 antenna, and RF transceiver, emitting mould train are set to master
On plate (1 mould group on the upside of battery in respective figure), the first receiving module and the second receiving module are set on subplate and (correspond to
2 mould groups on the downside of battery in attached drawing), and each receiving module is close to connected antenna and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
Mould group is received to be arranged close to third antenna group group.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 L, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 O2.
First external-connected port of the emission port TX1 connection emitting mould train of RF transceiver, the first frequency of RF transceiver
Second external-connected port of the first receiving port Nx RX1 connection emitting mould train of section, the 4th of the first frequency range of RF transceiver the
6th external-connected port of receiving port Nx RX4 connection emitting mould train, the third receiving port Nx of the first frequency range of RF transceiver
7th external-connected port of RX3 connection emitting mould train, the second receiving port Nx RX2 connection hair of the first frequency range of RF transceiver
Penetrate the third external-connected port of mould group.
Third antenna group connects 1 port P of the first switching switch (DP3T switch) of the first receiving module, the first switching
First T-port of switch corresponds to the auxiliary port of first receiving module, and second T-port of the first switching switch connects
First filter is connect, first filter connects the first LNA, first T of the first LNA connection second switching switch (DP2T switch)
Port, second T-port of third T-port connection the second switching switch of the first switching switch.
4th antenna sets and the second receiving module, the second receiving module internal components connection relationship and aforementioned third antenna with
First receiving module is similar, and details are not described herein again.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
One port P connection, realizes and emits signal by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
Two port P connections, realize and emit signal by the antenna of antenna sets.
In third transmit cycle, first T-port that electronic equipment controls the channel selection switch of emitting mould train is kept
It is connected to the 4th port P, realizes and signal is emitted by the antenna of antenna sets.
In 4th transmit cycle, first T-port that electronic equipment controls the channel selection switch of emitting mould train is kept
It is connected to the port third P, realizes and signal is emitted by the antenna of antenna sets.
As shown in fig. 4j, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is supported to emit poll;5. NR 2T4R (2 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains and 2 antenna sets, wherein each antenna sets include
2 antennas, RF transceiver, emitting mould train are set on mainboard (2 mould groups on the upside of battery in respective figure).
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets.
Wherein, the transmitting mould of the internal components structure and connection relationship of the first emitting mould train and the second emitting mould train such as Fig. 2 L
Shown in group, details are not described herein again.
First external-connected port of first emission port Nx TX1 the first emitting mould train of connection of RF transceiver, radio-frequency receiving-transmitting
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection of the first frequency range of device, the of RF transceiver
The third external-connected port of 4th receiving port Nx RX4 the first emitting mould train of connection of one frequency range, the second hair of RF transceiver
Penetrate the first external-connected port of port Nx TX2 the second emitting mould train of connection, the second receiving port of the first frequency range of RF transceiver
Second external-connected port of Nx RX2 the second emitting mould train of connection, the third receiving port Nx RX3 of the first frequency range of RF transceiver
Connect the third external-connected port of the second emitting mould train.First port PDET of RF transceiver connects the 8th of the first emitting mould train
External-connected port, the 2nd port PDET of RF transceiver connect the 8th external-connected port of the second emitting mould train.
First antenna group connects the 4th the 5th external-connected port of the first emitting mould train, the second antenna sets connection the second transmitting mould
4th the 5th external-connected port of group, the 7th external-connected port of the first emitting mould train connect the 11st external connection end of the second emitting mould train
Mouthful.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, while first T-port for controlling the channel selection switch of the first emitting mould train is kept and second
The connection of the port P is realized and emits signal by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P, while first T-port of the channel selection switch of the second emitting mould train of control and second end P
Mouth connection is realized and emits signal by the antenna of antenna sets.
In addition, this radio architectures is compatible with 1T4R SRS switching, that is, support to be dealt into 4 days from the first emitting mould train wheel
The ability of line group, i.e. the one the second transmit cycles are that the first emitting mould train passes through the 4th external-connected port and the 5th external-connected port;?
It is that the 11st external connection end that the 7th external-connected port comes out into the second emitting mould train is made a slip of the tongue channel selection switch in third transmit cycle
To the second antenna sets, the 4th transmit cycle is that the 7th external-connected port of the first emitting mould train comes out the into the second emitting mould train
11 external connection ends make a slip of the tongue channel selection switch to the second antenna sets.
As shown in Figure 4 K, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is supported to emit poll;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 2 receiving modules and 3 antenna sets, wherein every
A antenna sets include 1 antenna, and RF transceiver, emitting mould train, the first receiving module and the second receiving module are set to mainboard
On, and each receiving module is close to connected antenna and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
Mould group is received to be arranged close to conditioning chamber triantennary group group.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 L, receiving module
Internal components and connection relationship as shown in the receiving module of Fig. 1 O2, the AUX connection emitting mould train of the first receiving module the 7th outside
Port is connect to support to emit by respective antenna SRS TX signal or autonomous switching antenna and emit signal, the second receiving module
6th external-connected port of AUX connection emitting mould train is to support to emit SRS TX signal by respective antenna or independently switch antenna
Emit signal.
First external-connected port of the emission port TX1 connection emitting mould train of RF transceiver, the frequency range Nx of RF transceiver
The first receiving port Nx RX1 connection emitting mould train the second external-connected port, the third of the frequency range Nx of RF transceiver receives
Second receiving port Nx RX2 of the third external-connected port of port Nx RX3 connection emitting mould train, the frequency range Nx of RF transceiver connects
The port P of the second switching switch of the first receiving module is connect, the 4th receiving port Nx RX4 of the frequency range Nx of RF transceiver connects
Connect the port P of the second switching switch of the second receiving module.Outside the 8th of the port the PDET connection emitting mould train of RF transceiver
Connect port.
Second antenna sets connect the port P of the first switching switch (DP3T switch) of the first receiving module, and connection first is cut
Change the 7th external-connected port of any one auxiliary port connection emitting mould train of switch.Third antenna group connects the second receiving module
First switching switch the port P, the second receiving module connection first switching switch any auxiliary port connection transmitting mould
6th external-connected port of group.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
One port P connection, realizes and emits signal by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port and the of the channel selection switch of emitting mould train
Four port P connections, realize and emit signal by the antenna of antenna sets.
In third transmit cycle, first T-port that electronic equipment controls the channel selection switch of emitting mould train is kept
It is connected to second port P, realizes and signal is emitted by the antenna of antenna sets.
In 4th transmit cycle, first T-port that electronic equipment controls the channel selection switch of emitting mould train is kept
It is connected to the port third P, realizes and signal is emitted by the antenna of antenna sets.
As illustrated in fig. 4l, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is supported to emit poll;5. NR 2T4R (2 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules and 4 antenna sets, wherein every
A antenna sets include 1 antenna, and RF transceiver, the first emitting mould train and the second emitting mould train are set on mainboard, (corresponding
2 mould groups on the upside of battery in attached drawing), the first receiving module and the second receiving module are set on subplate (battery in respective figure
The mould group of downside 2), and each receiving module is close to connected antenna and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to third antenna group, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 L, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 O2.
First external-connected port of first emission port Nx TX1 the first emitting mould train of connection of RF transceiver, radio-frequency receiving-transmitting
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection of the first frequency range of device, the of RF transceiver
6th external-connected port of the 4th receiving port Nx RX4 the first emitting mould train of connection of one frequency range, the second hair of RF transceiver
Penetrate the first external-connected port of port Nx TX2 the second emitting mould train of connection, the second receiving port of the first frequency range of RF transceiver
Second external-connected port of Nx RX2 the second emitting mould train of connection, the third receiving port Nx RX3 of the first frequency range of RF transceiver
The tenth external-connected port of the second emitting mould train is connected, the first port PDET of RF transceiver connects the 8th of the first emitting mould train the
External-connected port, the 2nd port PDET of RF transceiver connect the 8th external-connected port of the second emitting mould train.
First antenna group connects the 4th external-connected port of the first emitting mould train, and the second antenna sets connect the second emitting mould train
4th external-connected port, third antenna group connect the port P of the first switching switch of the first receiving module, the 4th antenna sets connection the
The port P of second switching switch of two receiving modules, the second transmitting of the port P connection of the second switching switch of the first receiving module
The port P of 6th external-connected port of mould group, the second switching switch of the second receiving module connects outside the 6th of the first emitting mould train
Connect port.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
First T-port for being connected to first port P, while controlling the channel selection switch of the second emitting mould train is kept and third
The connection of the port P is realized and emits signal by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
First T-port for being connected to the 4th port P, while controlling the channel selection switch of the first emitting mould train is kept and third
The connection of the port P is realized and emits signal by the antenna of antenna sets.
As shown in fig. 4m, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is supported to emit poll;5. NR 2T4R (2 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 1 receiving module and 3 antenna sets, wherein every
A antenna sets include 1 antenna, and RF transceiver, the first emitting mould train and the second emitting mould train are set on mainboard, (corresponding
2 mould groups on the upside of battery in attached drawing), receiving module is set on subplate (1 mould group on the downside of battery in respective figure), and each
Receiving module is close to connected antenna and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, connects
Mould group is received to be arranged close to third antenna group.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 L, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 O2.
First external-connected port of first emission port Nx TX1 the first emitting mould train of connection of RF transceiver, radio-frequency receiving-transmitting
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection of the first frequency range of device, the of RF transceiver
Tenth external-connected port of the 4th receiving port Nx RX4 the first emitting mould train of connection of one frequency range, the second hair of RF transceiver
Penetrate the first external-connected port of port Nx TX2 the second emitting mould train of connection, the second receiving port of the first frequency range of RF transceiver
Second external-connected port of Nx RX2 the second emitting mould train of connection, the third receiving port Nx RX3 of the first frequency range of RF transceiver
The third external-connected port of the second emitting mould train is connected, the first port PDET of RF transceiver connects the 8th of the first emitting mould train the
External-connected port, the 2nd port PDET of RF transceiver connect the 8th external-connected port of the second emitting mould train.
First antenna group connects the 4th external-connected port of the first emitting mould train, and the second antenna sets connect the second emitting mould train
4th the 5th external-connected port, third antenna group connect the port P of the first switching switch of receiving module, and the second of receiving module cuts
The port P for changing switch connects the 6th external-connected port of the first emitting mould train.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
First T-port for being connected to first port P, while controlling the channel selection switch of the first emitting mould train is kept and third
The connection of the port P is realized and emits signal by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to the 4th port P, while first T-port for controlling the channel selection switch of the second emitting mould train is kept and second
The connection of the port P is realized and emits signal by the antenna of antenna sets.
As shown in Fig. 4 N, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is supported to emit poll;5. NR 2T4R (2 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains and 2 antenna sets, wherein each antenna sets include
2 antennas, RF transceiver, emitting mould train are set on mainboard (2 mould groups on the upside of battery in respective figure), and each reception
Mould group is close to connected antenna and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets.
Wherein, the transmitting mould of the internal components structure and connection relationship of the first emitting mould train and the second emitting mould train such as Fig. 2 L
Shown in group, details are not described herein again.
First external-connected port of first emission port Nx TX1 the first emitting mould train of connection of RF transceiver, radio-frequency receiving-transmitting
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection of the first frequency range of device, the of RF transceiver
The third external-connected port of 4th receiving port Nx RX4 the first emitting mould train of connection of one frequency range, the second hair of RF transceiver
Penetrate the first external-connected port of port Nx TX2 the second emitting mould train of connection, the second receiving port of the first frequency range of RF transceiver
Second external-connected port of Nx RX2 the second emitting mould train of connection, the third receiving port Nx RX3 of the first frequency range of RF transceiver
Connect the third external-connected port of the second emitting mould train.First port PDET of RF transceiver connects the 8th of the first emitting mould train
External-connected port, the 2nd port PDET of RF transceiver connect the 8th external-connected port of the second emitting mould train.
1 antenna of first antenna group connects the 11st external-connected port of the first emitting mould train, 1 day of third antenna group
Line connects the tenth external-connected port of the first emitting mould train, and 1 antenna of the second antenna sets connects the 11st of the second emitting mould train the
External-connected port, 1 antenna of third antenna group connect the tenth external-connected port of the first emitting mould train.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, while first T-port for controlling the channel selection switch of the first emitting mould train is kept and second
The connection of the port P is realized and emits signal by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P, while first T-port for controlling the channel selection switch of the second emitting mould train is kept and second
The connection of the port P is realized and emits signal by the antenna of antenna sets.
As shown in Fig. 4 O, which supports following functions: 1. 5G NR two-band;2. not supporting UL CA;③
Support DL CA;4. 4 antenna SRS is not supported to emit poll;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein every
A antenna sets include 1 antenna, and RF transceiver, emitting mould train, the first receiving module and the second receiving module are set to mainboard
Upper (3 mould groups on the upside of battery in respective figure), third receiving module is set on subplate (in respective figure 1 on the downside of battery
Mould group), and each receiving module is close to connected antenna and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 K, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 N2.
First external-connected port of the emission port Nx TX connection emitting mould train of RF transceiver, the first of RF transceiver
Second external-connected port of the first receiving port Nx RX1 connection emitting mould train of frequency range, the of the first frequency range of RF transceiver
8th external-connected port of four receiving port Nx RX4 connection emitting mould trains, the second receiving port of the first frequency range of RF transceiver
The port P of second switching switch of Nx RX2 the first receiving module of connection, the third receiving end of the first frequency range of RF transceiver
The port P of second switching switch of mouth Nx RX3 the second receiving module of connection.
Second antenna sets connect the port P of the first switching switch of the first receiving module, and third antenna group connection second connects
The port P of the first switching switch of mould group is received, the 4th antenna sets connect the port P of the first switching switch of third receiving module,
5th external-connected port of the port the P connection emitting mould train of the second switching switch of third receiving module.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is executing single frequency range (by taking Nx frequency range as an example)
During SRS4 days line wheel hairs or autonomous transmission switch:
In first transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
It is connected to first port P, realizes and signal is emitted by the antenna of antenna sets.
In second transmit cycle, electronic equipment controls first T-port of the first passage selection switch of emitting mould train
Holding is connected to second port P, is realized and is emitted signal by the antenna of antenna sets.
As shown in Fig. 4 P, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is not supported to emit poll;5. NR 1T4R (1 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 3 receiving modules and 4 antenna sets, wherein every
A antenna sets include 1 antenna, and RF transceiver, emitting mould train, the first receiving module are set on mainboard (in respective figure
2 mould groups on the upside of battery), the second receiving module and third receiving module are set on subplate (in respective figure 2 on the downside of battery
Mould group), and each receiving module is close to connected antenna and places.
Wherein, emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, and second connects
It receives mould group to be arranged close to third antenna group group, third receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 K, receiving module
As shown in the receiving module of Fig. 1 N2, the connection local terminal first of the first receiving module switches switch for internal components and connection relationship
The AUX conducting of AUX and the connection switching switch of local terminal second is to support to emit SRS TX signal by respective antenna or independently cut
Change antenna transmitting signal.
First external-connected port of the emission port TX1 connection emitting mould train of the first frequency range of RF transceiver, radio-frequency receiving-transmitting
Second external-connected port of the first receiving port Nx RX1 connection emitting mould train of the first frequency range of device, the first frequency of RF transceiver
The port P of first switching switch of second receiving port Nx RX2 the first receiving module of connection of section, the first of RF transceiver
8th external-connected port of the third receiving port Nx RX3 connection emitting mould train of frequency range, the 4th of the first frequency range of RF transceiver the
The port P of second switching switch of receiving port Nx RX4 connection third receiving module.The port PDET of RF transceiver connects
6th external-connected port of emitting mould train.
First antenna group connects the 4th external-connected port of the first emitting mould train, and the second antenna sets connect the first receiving module
The port P of first switching switch, the antenna of third antenna group connect the port P of the first switching switch of the second receiving module, the
The port P of first switching switch of the antenna connection third receiving module of four antenna sets, the second switching of the second receiving module are opened
5th external-connected port of the port the P connection emitting mould train of pass.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, realizes and signal is emitted by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to second port P, realizes and signal is emitted by the antenna of third antenna group.
As shown in Fig. 4 Q, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. not supporting 4 antenna SRS switching;5. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules and 4 antenna sets, wherein the
One antenna sets include 1 antenna, and the second antenna sets include 1 antenna, and third antenna group includes 1 antenna, the 4th antenna sets packet
Including 1 antenna, RF transceiver, the one the second emitting mould trains are set on mainboard (2 mould groups on the upside of battery in respective figure),
The one the second receiving modules are set on subplate (2 mould groups on the downside of battery in respective figure), and each emitting mould train or reception
Mould group is close to connected antenna sets and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group, and the second receiving module is arranged close to the 4th antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 K, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 N2.
First external-connected port of first emission port TX1 the first emitting mould train of connection of the frequency range Nx of RF transceiver, is penetrated
First external-connected port of the 4th emission port TX4 the second emitting mould train of connection of the frequency range Nx of frequency transceiver, RF transceiver
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection of frequency range Nx, the frequency range Nx of RF transceiver
Second receiving port Nx RX2 the second emitting mould train of connection the second external-connected port, the third of the frequency range Nx of RF transceiver connects
6th external-connected port of receiving end mouth Nx RX3 the second emitting mould train of connection, the 4th receiving port Nx of the frequency range Nx of RF transceiver
8th external-connected port of RX4 the first receiving module of connection, the first power sensor port PDET1 connection first hair of RF transceiver
Penetrate the 6th external-connected port of mould group, the 8th of second power sensor port PDET2 the second emitting mould train of connection of RF transceiver the
External-connected port.
The antenna of first antenna group connects the 4th external-connected port of the first emitting mould train, the second transmitting of the second antenna sets connection
4th external-connected port of mould group, the port P of the first switching switch of antenna the first receiving module of connection of third antenna group, the 4th
The antenna of antenna sets connects the port P of the first switching switch of the second receiving module.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, while first T-port for controlling the channel selection switch of the first emitting mould train is kept and second
The connection of the port P, and the bypass channel conducting of mould group is controlled and received, it realizes and signal is emitted by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P, while first T-port of the channel selection switch of the second emitting mould train of control and second end P
Mouth connection, and the bypass channel conducting of mould group is controlled and received, realize the antenna transmitting signal by the second antenna sets.
As shown in Fig. 4 R, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. not supporting 4 antenna SRS switching;5. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 1 receiving module and 3 antenna sets, wherein the
One antenna sets include 1 antenna, the second antenna sets include 2 antennas, third antenna group include 1 antenna, RF transceiver,
The one the second emitting mould trains are set on mainboard (2 mould groups on the upside of battery in respective figure), and receiving module is set on subplate
(2 mould groups on the downside of battery in respective figure), and each emitting mould train or receiving module are close to connected antenna sets and place.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, connects
Mould group is received to be arranged close to third antenna group group.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 K, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 N2.
First external-connected port of first emission port TX1 the first emitting mould train of connection of the frequency range Nx of RF transceiver, is penetrated
First external-connected port of the 4th emission port TX4 the second emitting mould train of connection of the frequency range Nx of frequency transceiver, RF transceiver
Second external-connected port of first receiving port Nx PRX the first emitting mould train of connection of frequency range Nx, the frequency range Nx's of RF transceiver
The third of second external-connected port of second receiving port Nx RX2 the second emitting mould train of connection, the frequency range Nx of RF transceiver receives
The third external-connected port of port Nx RX3 the second emitting mould train of connection, the 4th receiving port Nx of the frequency range Nx of RF transceiver
8th external-connected port of RX4 the first receiving module of connection, the first power sensor port PDET1 connection first hair of RF transceiver
Penetrate the 6th external-connected port of mould group, the 8th of second power sensor port PDET2 the second emitting mould train of connection of RF transceiver the
External-connected port.
The antenna of first antenna group connects the 4th external-connected port of the first emitting mould train, and 2 antennas of the second antenna sets connect
The the 4th the 5th external-connected port of the second emitting mould train is connect, the first switching switch of the antenna connection receiving module of third antenna group
The port P.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, while first T-port for controlling the channel selection switch of the first emitting mould train is kept and second
The connection of the port P, and the bypass channel conducting of mould group is controlled and received, it realizes and signal is emitted by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P, while first T-port of the channel selection switch of the second emitting mould train of control and second end P
Mouth connection realizes and emits signal by second antenna of the second antenna sets, realization passes through first antenna of the second antenna sets
Emit signal.
As shown in fig. 4s, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. not supporting 4 antenna SRS switching;5. NR 1T4R (totally 1 tunnel emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 2 receiving modules and 3 antenna sets, wherein the
One antenna sets include 2 antennas, the second antenna sets include 1 antenna, third antenna group include 1 antenna, RF transceiver,
First receiving module is set on mainboard (2 mould groups on the upside of battery in respective figure), and the second receiving module is set on subplate
(2 mould groups on the downside of battery in respective figure), and each receiving module is close to connected antenna and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, the
Two receiving modules are arranged close to third antenna group group.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 K, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 N2.First receiving module connect local terminal first switching switch AUX and
The AUX conducting of second switching switch is to support to emit by respective antenna SRS TX signal or autonomous switching antenna transmitting letter
Number.
First external-connected port of the emission port TX1 connection emitting mould train of the first frequency range of RF transceiver, radio-frequency receiving-transmitting
Second external-connected port of the first receiving port Nx PRX connection emitting mould train of the first frequency range of device, the first frequency of RF transceiver
The port P of second switching switch of second receiving port Nx RX2 the first receiving module of connection of section, the first of RF transceiver
The third external-connected port of the third receiving port Nx RX3 connection emitting mould train of frequency range, the 4th of the first frequency range of RF transceiver the
The port P of first switching switch of receiving port Nx RX4 the second receiving module of connection.The port PDET of RF transceiver connects
6th external-connected port of emitting mould train.
The antenna of first antenna group connects the 4th external-connected port of the first emitting mould train, and the second antenna sets connection first receives
The port P of first switching switch of mould group, the antenna of third antenna group connect the end P of the first switching switch of the second receiving module
Mouthful.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, realizes and signal is emitted by first antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to second port P, realizes and signal is emitted by second antenna of first antenna group.
As shown in Fig. 4 T, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. not supporting 4 antenna SRS switching;5. NR 1T4R (totally 1 tunnel emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 2 receiving modules and 3 antenna sets, wherein the
One antenna sets include 2 antennas, the second antenna sets include 1 antenna, third antenna group include 1 antenna, RF transceiver,
Emitting mould train is set on mainboard (1 mould group on the upside of battery in respective figure), the first receiving module, the setting of the second receiving module
In (2 mould groups on the downside of battery in respective figure) on subplate, and each receiving module is close to connected antenna and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, the
Two receiving modules are arranged close to third antenna group group.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 K, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 N2.
First external-connected port of the emission port TX1 connection emitting mould train of the first frequency range of RF transceiver, radio-frequency receiving-transmitting
Second external-connected port of the first receiving port Nx PRX connection emitting mould train of the first frequency range of device, the first frequency of RF transceiver
The third external-connected port of second receiving port Nx RX2 connection emitting mould train of section, the third of the first frequency range of RF transceiver connect
The port P of second switching switch of receiving end mouth Nx RX3 the first receiving module of connection, the 4th of the first frequency range of RF transceiver the
The port P of second switching switch of receiving port Nx RX4 the second receiving module of connection.The port PDET of RF transceiver connects
6th external-connected port of emitting mould train.
Two antennas of first antenna group are separately connected fourth, fifth external-connected port of the first emitting mould train, the second antenna sets
1 antenna connect the first receiving module the first switching switch the port P, the antenna connection receiving module of third antenna group
The port P of first switching switch.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, realizes and signal is emitted by first antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to second port P, realizes and signal is emitted by second antenna of first antenna group.
As shown in fig. 4u, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. not supporting 4 antenna SRS switching;5. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive).
The 5G radio architectures include RF transceiver, 2 emitting mould trains and 2 antenna sets, wherein first antenna group includes
2 antennas, the second antenna sets include 2 antennas, and RF transceiver, the one the second emitting mould trains are set on mainboard that (correspondence is attached
2 mould groups on the upside of battery in figure), and each emitting mould train is close to connected antenna sets and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship are as shown in the emitting mould train of Fig. 2 K.
First external-connected port of first emission port TX1 the first emitting mould train of connection of the frequency range Nx of RF transceiver, is penetrated
First external-connected port of the 4th emission port TX4 the second emitting mould train of connection of the frequency range Nx of frequency transceiver, RF transceiver
Second external-connected port of first receiving port Nx PRX the first emitting mould train of connection of frequency range Nx, the frequency range Nx's of RF transceiver
The third of second external-connected port of second receiving port Nx RX2 the second emitting mould train of connection, the frequency range Nx of RF transceiver receives
The third external-connected port of port Nx RX3 the second emitting mould train of connection, the 4th receiving port Nx of the frequency range Nx of RF transceiver
The third external-connected port of RX4 the first receiving module of connection, the first power sensor port PDET1 connection first hair of RF transceiver
Penetrate the 6th external-connected port of mould group, the 8th of second power sensor port PDET2 the second emitting mould train of connection of RF transceiver the
External-connected port.
4th the 5th external-connected port of 2 antennas the first emitting mould train of connection of first antenna group, 2 of the second antenna sets
Antenna connects the 4th the 5th external-connected port of the second emitting mould train.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, while first T-port of the channel selection switch of the first emitting mould train of control and second end P
Mouth connection realizes that first antenna for passing through first antenna group emits signal.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P, while first T-port for controlling the channel selection switch of the second emitting mould train is kept and second
The connection of the port P is realized and emits signal by first antenna of the second antenna sets.
As shown in Fig. 4 V, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. not supporting 4 antenna SRS switching;5. NR 1T4R (totally 1 tunnel emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 1 emitting mould train, 2 receiving modules and 3 antenna sets, wherein the
One antenna sets include 2 antennas, the second antenna sets include 1 antenna, third antenna group include 1 antenna, RF transceiver,
Emitting mould train, the first receiving module, the second receiving module are set on mainboard (2 mould groups on the upside of battery in respective figure), and
Each receiving module is close to connected antenna and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the first receiving module is arranged close to the second antenna sets, the
Two receiving modules are arranged close to third antenna group group.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 K, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 N2.
First external-connected port of the emission port TX1 connection emitting mould train of the first frequency range of RF transceiver, radio-frequency receiving-transmitting
Second external-connected port of the first receiving port Nx PRX connection emitting mould train of the first frequency range of device, the first frequency of RF transceiver
The port P that second switching of second receiving port Nx RX2 the first receiving module of connection of section switchs, the of RF transceiver
The third external interface of the third receiving port Nx RX3 connection emitting mould train of one frequency range, the of the first frequency range of RF transceiver
The port P of second switching switch of four receiving port Nx RX4 the second receiving modules of connection.The port PDET of RF transceiver connects
Connect the 6th external-connected port of emitting mould train.
Two antennas of first antenna group are separately connected fourth, fifth external-connected port of the first emitting mould train, the second antenna sets
1 antenna connect the first receiving module first switching switch the port P, third antenna group antenna connection second receive mould
The port P of second switching switch of group.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, realizes and signal is emitted by first antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to second port P, realizes and signal is emitted by second antenna of first antenna group.
As shown in Fig. 4 W, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. not supporting 4 antenna SRS switching;5. NR 2T4R (totally 4 tunnels emit 8 tunnels and receive).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 2 receiving modules and 4 antenna sets, wherein the
One antenna sets include 1 antenna, and the second antenna sets include 1 antenna, and third antenna group includes 1 antenna, the 4th antenna sets packet
Including 1 antenna, RF transceiver, the one the second emitting mould trains are set on mainboard (2 mould groups on the upside of battery in respective figure),
The one the second receiving modules are set on subplate (2 mould groups on the downside of battery in respective figure), and each emitting mould train or reception
Mould group is close to connected antenna sets and places.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, the
One receiving module is arranged close to third antenna group group, and the second receiving module is arranged close to the 4th antenna sets group.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 K, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 N2.
First external-connected port of first emission port TX1 the first emitting mould train of connection of the frequency range Nx of RF transceiver, is penetrated
First external-connected port of the 4th emission port TX4 the second emitting mould train of connection of the frequency range Nx of frequency transceiver, RF transceiver
Second external-connected port of first receiving port Nx PRX the first emitting mould train of connection of frequency range Nx, the frequency range Nx's of RF transceiver
The third of second external-connected port of second receiving port Nx RX2 the second emitting mould train of connection, the frequency range Nx of RF transceiver receives
6th external-connected port of port Nx RX3 the second emitting mould train of connection, the 4th receiving port Nx of the frequency range Nx of RF transceiver
8th external-connected port of RX4 the first emitting mould train of connection, the first power sensor port PDET1 connection first hair of RF transceiver
Penetrate the 6th external-connected port of mould group, the 8th of second power sensor port PDET2 the second emitting mould train of connection of RF transceiver the
External-connected port.
The antenna of first antenna group connects the 4th external-connected port of the first emitting mould train, the antenna connection of the second antenna sets the
4th external-connected port of two emitting mould trains, the port P of the first switching switch of the antenna connection receiving module of third antenna group, the
The port P of first switching switch of the antenna connection receiving module of four antenna sets.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, realizes and signal is emitted by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P, realizes and signal is emitted by first antenna of the second antenna sets.
In third transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to second port P, and controls and receives the bypass channel conducting of mould group, realized and letter is emitted by the antenna of third antenna group
Number.
In 4th transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
Holding is connected to second port P, and controls and receives the bypass channel conducting of mould group, is realized and is sent out by the antenna of the 4th antenna sets
Penetrate signal.
As shown in Fig. 4 X, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is not supported to emit poll;5. NR 2T4R (2 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains, 1 receiving module and 3 antenna sets, wherein the
One antenna sets include 1 antenna, the second antenna sets include 2 antennas, third antenna group include 1 antenna, RF transceiver,
The one the second emitting mould trains are set on mainboard (2 mould groups on the upside of battery in respective figure), and receiving module is set on subplate
(2 mould groups on the downside of battery in respective figure), and each emitting mould train or receiving module are close to connected antenna sets and place.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets, connects
Mould group is received to be arranged close to third antenna group group.
Wherein, the internal components structure of emitting mould train and connection relationship be as shown in the emitting mould train of Fig. 2 K, receiving module
Internal components and connection relationship are as shown in the receiving module of Fig. 1 N2.
First external-connected port of first emission port Nx TX1 the first emitting mould train of connection of the frequency range Nx of RF transceiver,
First external-connected port of second emission port Ny TX2 the second emitting mould train of connection of frequency range Nx, the frequency range Nx's of RF transceiver
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection, the second of the frequency range Nx of RF transceiver receive
First port P of the second switching switch of port Nx RX2 the first receiving module of connection, the of the frequency range Nx of RF transceiver
Second external-connected port of two receiving port Ny RX2 the second emitting mould trains of connection, the third receiving end of the frequency range Nx of RF transceiver
8th external-connected port of mouth Nx RX3 the second emitting mould train of connection, the 4th receiving port Nx RX4 of the frequency range Nx of RF transceiver
Connect the 8th external-connected port of the first receiving module, the first power sensor port PDET1 connection first transmitting of RF transceiver
6th external-connected port of mould group, second power sensor port PDET2 the second emitting mould train of connection of RF transceiver the 6th outside
Connect port.
The antenna of first antenna group connects the 4th external-connected port of the first emitting mould train, and 2 antennas of the second antenna sets connect
The the 4th the 5th external-connected port of the second emitting mould train is connect, the first switching switch of the antenna connection receiving module of third antenna group
The port P.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, while first T-port for controlling the channel selection switch of the first emitting mould train is kept and second
The connection of the port P, and the bypass channel conducting of mould group is controlled and received, it realizes and signal is emitted by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P, while first T-port of the channel selection switch of the second emitting mould train of control and second end P
Mouth connection is realized and emits signal by first antenna of the second antenna sets.
As shown in Fig. 4 Y, which supports following functions: 1. 5G NR one-segment;2. not supporting UL CA;③
DL CA is not supported;4. 4 antenna SRS is not supported to emit poll;5. NR 2T4R (2 tunnel of one-segment emits 4 tunnels and receives).
The 5G radio architectures include RF transceiver, 2 emitting mould trains and 2 antenna sets, wherein each antenna sets include
2 antennas, RF transceiver, the one the second emitting mould trains are set on mainboard (2 mould groups on the upside of battery in respective figure), and
The antenna sets that each emitting mould train was close to be connected connected are placed.
Wherein, the first emitting mould train is arranged close to first antenna group, and the second emitting mould train is arranged close to the second antenna sets.
Wherein, the internal components structure of emitting mould train and connection relationship are as shown in the emitting mould train of Fig. 2 K.
First external-connected port of first emission port Nx TX1 the first emitting mould train of connection of the frequency range Nx of RF transceiver,
First external-connected port of second emission port Ny TX2 the second emitting mould train of connection of frequency range Nx, the frequency range Nx's of RF transceiver
Second external-connected port of first receiving port Nx RX1 the first emitting mould train of connection, the second of the frequency range Nx of RF transceiver receive
First port P of the second switching switch of port Nx RX2 the first receiving module of connection, the of the frequency range Nx of RF transceiver
Second external-connected port of two receiving port Ny RX2 the second emitting mould trains of connection, the third receiving end of the frequency range Nx of RF transceiver
The third external-connected port of mouth Nx RX3 the second emitting mould train of connection, the 4th receiving port Nx RX4 of the frequency range Nx of RF transceiver
Connect the third external-connected port of the first receiving module, the first power sensor port PDET1 connection first transmitting of RF transceiver
6th external-connected port of mould group, second power sensor port PDET2 the second emitting mould train of connection of RF transceiver the 6th outside
Connect port.
The antenna of first antenna group connects the 4th external-connected port of the first emitting mould train, and 2 antennas of the second antenna sets connect
The the 4th the 5th external-connected port of the second emitting mould train is connect, the first switching switch of the antenna connection receiving module of third antenna group
The port P.
Electronic equipment comprising above-mentioned radio architectures controls the target frequency bands of RF transceiver described in the radio frequency system
Emission port be connected with the transmitting path between target antenna group, signal is emitted by antenna in the target antenna group.
In the specific implementation, the electronic equipment comprising above-mentioned radio architectures is in the hair for executing single frequency range (by taking Nx frequency range as an example)
During penetrating antenna switching:
In first transmit cycle, electronic equipment controls first T-port of the channel selection switch of the first emitting mould train
It is connected to first port P, while first T-port for controlling the channel selection switch of the first emitting mould train is kept and second
The connection of the port P, and the bypass channel conducting of mould group is controlled and received, it realizes and signal is emitted by the antenna of first antenna group.
In second transmit cycle, electronic equipment controls first T-port of the channel selection switch of the second emitting mould train
It is connected to first port P, while first T-port of the channel selection switch of the second emitting mould train of control and second end P
Mouth connection is realized and emits signal by first antenna of the second antenna sets.
It should be noted that external-connected port described in the embodiment of the present application can be the end of module internal device body
Mouthful, it is also possible to the separate physical port drawn by electric wire, does not do unique restriction herein.(n1 is greater than above-mentioned all kinds of n1Pn2T
Equal to 2, n2 be more than or equal to 2) switch (channel selection switch including description, power detection selection switch, transceiver toggle switch,
Any switches such as the one the second switching switches, receiving port selection switch) the connection relationship of internal port can be full connection
Or simplify connection, it specifically can according to need and be correspondingly arranged, in 4P4T switch, first port P can only connect first
A T-port, second port P can connect 3 T-ports entirely, and full connection refers to have the inside controlable electric current knot for establishing access
Structure, such as construct and control by switching tube.
It should be noted that the coaxial line in radio frequency system described in the embodiment of the present application, it is also possible to be substituted for liquid crystal
Polymer material LCP soft board etc..
Fourth aspect, the embodiment of the present application provide a kind of electronic equipment, including as described in above-described embodiment either side
Radio frequency system, the radio frequency system includes RF transceiver, rf processing circuitry and at least two antenna sets, and the radio frequency is received
It sends out device and connects the rf processing circuitry, the rf processing circuitry connects at least two antenna sets, the radio frequency system branch
4 antenna of downlink receive capabilities simultaneously are held, at least two antenna sets include m branch antenna altogether, and m is more than or equal to 4 and is less than or equal to 8;Institute
Stating rf processing circuitry includes mould group identical with the group number quantity of at least two antenna sets, and the mould group includes transmitting mould
Group or emitting mould train and receiving module, and the antenna sets that each emitting mould train is connected close to each emitting mould train, often
The antenna sets that a receiving module is connected close to each receiving module;
The electronic equipment include at least it is following any one: mobile terminal, base station.
It is the embodiment of the embodiment of the present application above, it is noted that those skilled in the art are come
It says, under the premise of not departing from the embodiment of the present application principle, several improvements and modifications can also be made, these improvements and modifications
It is considered as the protection scope of the application.
Claims (16)
1. a kind of receiving module, which is characterized in that including at least signal receiving channel, the first switching switch, second switch all the way
Switch;
The first switching switch connection at least signal receiving channel all the way, described at least signal receiving channel connects all the way
The second switching switch, the first switching switch or the second switching switch include that n1Pn2T is switched, and every road signal connects
Receiving channel includes filter Filter and low-noise amplifier LNA, the LNA connection Filter;
First switching switchs the antenna for connecting the corresponding antenna sets of the receiving module, and the second switching switch is used
In connection emitting mould train and/or RF transceiver, and the receiving module is arranged close to the antenna sets, and n1 is positive integer, n2
For the integer more than or equal to 2.
2. receiving module according to claim 1, which is characterized in that the receiving module it is described first switching switch and
It is additionally provided with 1 path built-in bypass channel between the second switching switch, the built in bypass channel is for connecting emitting mould train
To support the receiving module signal transmission function.
3. receiving module according to claim 2, which is characterized in that the receiving module further includes 1 auxiliary port
AUX, AUX connection the first switching switch, the auxiliary port is for connecting emitting mould train to support the reception mould
Group signal transmission function.
4. receiving module according to claim 1, which is characterized in that the receiving module further includes 2 auxiliary ports
AUX, i.e. the first AUX and the 2nd AUX, the switching of the first AUX connection first switch, the switching of the 2nd AUX connection second are opened
It closes, external bypass channel is provided between the first AUX and the 2nd AUX, the external bypass channel is for connecting hair
Mould group is penetrated to support the signal transmission function of the receiving module.
5. receiving module according to claim 1, which is characterized in that the receiving module further includes 3 auxiliary ports
AUX, i.e. the first AUX, the 2nd AUX and the 3rd AUX, the first AUX connect the first switching switch with the 2nd AUX,
The switching of 3rd AUX connection second switch, the first AUX or the 2nd AUX are for connecting emitting mould train to support
The signal transmission function of the receiving module;Alternatively,
First AUX and the 3rd AUX or the 2nd AUX and the 3rd AUX is used to access external bypass channel,
The external bypass channel is for connecting emitting mould train to support the signal transmission function of the receiving module.
6. according to the described in any item receiving modules of claim 3-5, which is characterized in that the receiving module supports signal transmitting
Function;
When the receiving module is set on the mainboard of electronic equipment, the connection of the receiving module the first switching switch
1 AUX is for connecting emitting mould train;Alternatively,
When the receiving module is set on the subplate of electronic equipment, the first AUX is connect or described with the 3rd AUX
2nd AUX is connect with the 3rd AUX.
7. receiving module according to claim 6, which is characterized in that the receiving module is specifically close to the antenna sets
Feed point position.
8. receiving module according to claim 7, which is characterized in that the receiving module further includes combiner, the conjunction
Road device is for being combined a plurality of signal receiving channel to support a plurality of receiving channel to work at the same time.
9. receiving module according to claim 8, which is characterized in that the receiving module further includes shielded layer.
10. receiving module according to claim 9, which is characterized in that the receiving module even further includes mobile Enterprise Administration Office
Reason device interface MIPI and/or universal input/output GPIO control unit, the MIPI and/or the GPIO control unit are used for
The device in the emitting mould train is controlled, the device includes any of the following: the first switching switch, the second switching switch.
11. receiving module according to claim 10, which is characterized in that the receiving module includes 2 low noise amplifications
Device LNA, 2 filters, 2 switching switches and built in bypass channel;Wherein, the port P of the first switching switch is for connecting
First T-port of the antenna of antenna sets, the first switching switch connects first filter, and first filter connects the first LNA,
First T-port of the switching of the first LNA connection second switch, the second T-port connection second of the first switching switch
Filter, the 2nd LNA of the 2nd Filter connection, the second T-port of the 2nd LNA connection second switching switch, described first
Switch and connects the built in bypass channel between the third T-port of switch and the third T-port of the second switching switch, it is described
The port P of second switching switch is for connecting emitting mould train.
12. receiving module according to claim 1-5, which is characterized in that the receiving module includes 2 low noises
Acoustic amplifier LNA, 2 filters, 2 combiners, 2 switching switches, the built-in channels Bypass;Wherein, first switching
The port P of switch connects the antenna of corresponding antenna sets, the first combining of first T-port connection of the first switching switch
Device, first combiner connect first filter, second filter, and first filter connects the first LNA, and second filter connects
The 2nd LNA, the first LNA, the 2nd LNA second combiner of connection are met, the second combiner connection described second is cut
Change first T-port of switch, second T of second T-port of the first switching switch and the second switching switch
The built-in channel Bypass is connected between port.
13. receiving module according to claim 1-5, which is characterized in that the receiving module includes 2 low noises
Acoustic amplifier LNA, 2 filters, 2 switching switches, 1 auxiliary port AUX, the built-in channel Bypass, 2 switchings are opened
The first switching switch in the Central Shanxi Plain is that DP4T is switched, and the second switching switch is that DP3T is switched, and the auxiliary port is for connecting transmitting
Mould group, the first T-port of the first switching switch connect first filter, and the first filter connects the first LNA, described
First LNA connects the first T-port of the second switching switch, the second filter of the second T-port connection of the first switching switch
Wave device, the second filter connect the 2nd LNA, and the 2nd LNA connects the second T-port of the second switching switch, the
The third T-port of one switching switch connects the AUX.
14. receiving module according to claim 1-5, which is characterized in that the receiving module includes 2 low noises
Acoustic amplifier LNA, 2 filters, 2 switching switches, 3 auxiliary port AUX, described 2 switch the first switching switch opened
For DP4T switch, the second switching switch is that DP3T is switched, and the second T-port of the first switching switch connects first filter,
The first filter connects the first LNA, the first T-port of the switching of the first LNA connection second switch, first switching
The third T-port of switch connects second filter, and the second filter connects the 2nd LNA, and the 2nd LNA connection second is cut
The second T-port of switch is changed, the first T-port and the 4th T-port of the first switching switch are separately connected the first AUX and the 2nd AUX,
The third T-port of the second switching switch connects the 3rd AUX, the first AUX and the 3rd AUX or described second
AUX and the 3rd AUX is for connecting the external channel Bypass, and the first AUX or the 2nd AUX is for connecting transmitting mould
Group.
15. receiving module according to claim 1-5, which is characterized in that the receiving module includes 2 low noises
Acoustic amplifier LNA, 2 filters, 2 switching switches, 2 auxiliary port AUX, the first T-port connection of the first switching switch
First filter, the first filter connect the first LNA, and the first LNA connection second switches the first T-port of switch,
Second T-port of the first switching switch connects second filter, and the second filter connects the 2nd LNA, and the 2nd LNA connects
The second T-port of the second switching switch is connect, the third T-port of the first switching switch connects the first AUX, second switching
The third T-port of switch connects the 2nd AUX, and the first switching switch and the second switching switch are DP3T switch, institute
The first AUX and the 2nd AUX is stated for connecting the external channel Bypass, alternatively, the first AUX is for connecting emitting mould train
Transmitting SRS TX port.
16. receiving module according to claim 1-5, which is characterized in that the receiving module includes 1 low noise
Acoustic amplifier LNA, 1 filter, 2 switching switches, 3 auxiliary port AUX, the first T-port connection of the first switching switch
The second T-port of first AUX, the first switching switch connect filter, and the filter connects LNA, and the LNA connection second is cut
Changing the first T-port of switch, the third T-port of the first switching switch connects the 2nd AUX, and the of the second switching switch
Two T-ports connect the 3rd AUX;The first switching switch is that SP3T is switched, and the second switching switch is SPDT switch;It is described
First AUX and the 3rd AUX or the 2nd AUX and the 3rd AUX is for connecting the external channel Bypass, Huo Zhesuo
The first AUX or the 2nd AUX is stated for connecting emitting mould train.
Priority Applications (4)
Application Number | Priority Date | Filing Date | Title |
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CN201821172435.4U CN209057208U (en) | 2018-07-23 | 2018-07-23 | Receiving module and Related product |
PCT/CN2019/097164 WO2020020110A1 (en) | 2018-07-23 | 2019-07-22 | Receiving module, transmitting module, and radio frequency system |
US16/519,646 US10715201B2 (en) | 2018-07-23 | 2019-07-23 | Receiving module, transmitting module, and radio frequency system |
EP19187926.1A EP3609083B1 (en) | 2018-07-23 | 2019-07-23 | Receiving module, transmitting module, and radio frequency system |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN201821172435.4U CN209057208U (en) | 2018-07-23 | 2018-07-23 | Receiving module and Related product |
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Publication Number | Publication Date |
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CN209057208U true CN209057208U (en) | 2019-07-02 |
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ID=67046832
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2020020110A1 (en) * | 2018-07-23 | 2020-01-30 | Guangdong Oppo Mobile Telecommunications Corp., Ltd. | Receiving module, transmitting module, and radio frequency system |
CN111342847A (en) * | 2020-02-13 | 2020-06-26 | 芯朴科技(上海)有限公司 | Method for adjusting output power |
CN111682885A (en) * | 2020-06-09 | 2020-09-18 | 芯朴科技(上海)有限公司 | 1T2R radio frequency circuit and wireless communication equipment |
US11165484B2 (en) | 2018-07-23 | 2021-11-02 | Guangdong Oppo Mobile Telecommunications Corp., Ltd. | Radio frequency system, method for controlling antenna switching, and related products |
CN116388795A (en) * | 2023-06-07 | 2023-07-04 | 石家庄银河微波技术股份有限公司 | Filter switch controller, radio frequency antenna and radio frequency antenna system |
-
2018
- 2018-07-23 CN CN201821172435.4U patent/CN209057208U/en active Active
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2020020110A1 (en) * | 2018-07-23 | 2020-01-30 | Guangdong Oppo Mobile Telecommunications Corp., Ltd. | Receiving module, transmitting module, and radio frequency system |
US11165484B2 (en) | 2018-07-23 | 2021-11-02 | Guangdong Oppo Mobile Telecommunications Corp., Ltd. | Radio frequency system, method for controlling antenna switching, and related products |
CN111342847A (en) * | 2020-02-13 | 2020-06-26 | 芯朴科技(上海)有限公司 | Method for adjusting output power |
CN111342847B (en) * | 2020-02-13 | 2021-11-30 | 芯朴科技(上海)有限公司 | Method for adjusting output power |
CN111682885A (en) * | 2020-06-09 | 2020-09-18 | 芯朴科技(上海)有限公司 | 1T2R radio frequency circuit and wireless communication equipment |
CN111682885B (en) * | 2020-06-09 | 2022-10-04 | 芯朴科技(上海)有限公司 | 1T2R radio frequency circuit and wireless communication equipment |
CN116388795A (en) * | 2023-06-07 | 2023-07-04 | 石家庄银河微波技术股份有限公司 | Filter switch controller, radio frequency antenna and radio frequency antenna system |
CN116388795B (en) * | 2023-06-07 | 2023-09-05 | 石家庄银河微波技术股份有限公司 | Filter switch controller, radio frequency antenna and radio frequency antenna system |
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