CN217767211U - Beidou/GPS dual-mode digital high-precision synchronous time service equipment and system - Google Patents

Abstract

The utility model discloses a big dipper GPS bimodulus digit high accuracy synchronization time service equipment and system, this equipment contains: the system comprises a radio frequency time service component, a high-precision network time service component, a power supply component and a UI component; wherein, high accuracy network time service subassembly contains: the first radio frequency receiver components are used for receiving radio frequency signals; the first active amplification component is connected to the first two radio frequency receiver components and is used for enhancing the strength of the radio frequency signals; the radio frequency signal-to-digital signal component is connected to the first active amplification component and is used for converting the radio frequency signal into a digital signal; the FPGA component is used for receiving the digital signal and realizing PTP protocol stack and SyncE functions; the external interface component is connected to the FPGA component and used for providing a time service interface output function; and the core management component is used for providing a device management function. The utility model discloses a big dipper GPS bimodulus digit high accuracy synchronization time service equipment and system utilizes current A equipment to carry out big dipper & GPS bimodulus digit high accuracy time service to BBU equipment as the clock transmission.

Description

Beidou/GPS dual-mode digital high-precision synchronous time service equipment and system

Technical Field

The utility model belongs to the technical field of the satellite time service, concretely relates to big dipper GPS bimodulus digit high accuracy synchronization time service equipment and system.

Background

The existing synchronous time service system of the 4G base station mainly depends on a GPS satellite, but the BBU equipment of the existing network 4G base station does not support Beidou time service, the inventory is large, and if each BBU equipment is upgraded and modified, the modification cost is high and the construction amount is large.

At present, the existing equipment in the market has single function and only supports PTP time service or only supports radio frequency (GPS) time service. The equipment supporting PTP time service has relatively weak time service capability, relatively large frequency deviation and low time accuracy, and cannot meet the requirements of a mobile network. The radio frequency time service supporting equipment only supports GPS time service, and the current situation that the BBU equipment of the existing network 4G base station needs to support Beidou time service cannot be solved.

SUMMERY OF THE UTILITY MODEL

The utility model provides a big dipper GPS bimodulus digit high accuracy synchronization time service equipment and system solve the above-mentioned technical problem who mentions, specifically adopt following technical scheme:

a big dipper/GPS bimodulus digital high accuracy synchronization time service equipment, contains:

the system comprises a radio frequency time service component, a high-precision network time service component, a power supply component and a UI component;

the power supply assembly is connected to the radio frequency time service assembly and the high-precision network time service assembly and provides electric energy for the Beidou/GPS dual-mode digital high-precision synchronous time service equipment;

the UI component is connected to the radio frequency time service component and the high-precision network time service component;

the high-precision network time service component comprises: the system comprises two radio frequency receiver assemblies I, an active amplification assembly I, a radio frequency signal-to-digital signal assembly, an FPGA assembly, an external interface assembly and a core management assembly;

the first active amplification component is connected to the first two radio frequency receiver components;

the radio frequency signal-to-digital signal component is connected to the first active amplification component;

the external interface component is connected to the FPGA component;

the core management component is connected to the first active amplification component, the radio frequency signal-to-digital signal component, the FPGA component and the external interface component;

the radio frequency time service assembly comprises: two radio frequency receiver assemblies II, an active amplification assembly II and a distributor assembly.

The second active amplification component is connected to the second two radio frequency receiver components;

the distributor component is connected to the second active amplification component.

Further, the first radio frequency receiver component and the second radio frequency receiver component have the same structure, and both the first radio frequency receiver component and the second radio frequency receiver component comprise: the low-noise amplification module I and the power supply module I are connected;

and the power supply module I is connected to the low-noise amplification module I.

Further, the first active amplification module and the second active amplification module have the same structure, and both the first active amplification module and the second active amplification module comprise: the low-noise amplification module II, the band-pass filtering module, the dual-channel switching module and the power supply module II are arranged in the power supply module I;

the band-pass filtering module is connected to the second low-noise amplifying module;

the dual-channel switching module is connected to the second low-noise amplification module;

and the power supply module II is connected to the low-noise amplification module II, the band-pass filtering module and the dual-channel switching module.

Further, the component for converting the rf signal into the digital signal comprises: the radio frequency receiving module, the radio frequency analyzing module, the time service module, the external interface module and the power supply module III are arranged in the radio frequency receiving module;

the radio frequency analysis module is connected to the radio frequency receiving module;

the time service module is connected to the radio frequency analysis module;

the external interface module is connected to the time service module;

and the power supply module III is connected to the radio frequency receiving module, the radio frequency analysis module, the time service module and the external interface module.

Further, the core management component includes: the device comprises a detection function module, a control function module and a display function module;

the detection function module is used for detecting the state of the distributor assembly connected with the time service equipment;

the control function module is connected to the external interface component and the active amplification component;

the display function module is connected to the UI component.

Further, the FPGA module comprises: a protocol stack module and a phase-locked loop module;

the phase-locked loop module is connected to the protocol stack module.

Further, the external interface assembly includes: the system comprises a dry contact point warning module and a high-precision network time service output module;

and the dry contact point warning module is connected with the high-precision network time service output module.

Further, the distributor assembly comprises a power supply detection module and an impedance matching module.

Further, the power supply assembly comprises a first power supply assembly and a second power supply assembly;

the first power supply assembly and the second power supply assembly have the same structure;

the first and second power supply components each comprise: the power supply conversion module and the power supply isolation module;

the power isolation module is connected to the power conversion module.

A big dipper/GPS bimodulus digital high accuracy synchronization time service system, contains: the device A comprises a device A, a plurality of BBU devices and any one of the Beidou/GPS dual-mode digital high-precision synchronous time service devices;

the A equipment is connected to Beidou/GPS dual-mode digital high-precision synchronous time service equipment;

several BBU devices are connected to the a device.

The utility model discloses an useful part lies in the synchronous time service equipment of big dipper GPS bimodulus digit high accuracy and system that provides, utilizes current A equipment to carry out big dipper & GPS bimodulus digit high accuracy time service as clock transfer to BBU equipment, and it regards as a switch that has the PTP function with A equipment in the IPRAN network deployment, utilizes this switch to carry out the clock transfer, forwards BBU equipment with big dipper or GPS high accuracy clock signal that time service equipment received. The method innovatively provides the improvement of the Beidou time service capability by using the existing network equipment and resources on the premise of no network interruption, and the improvement cost and the construction difficulty are greatly reduced.

The utility model discloses an useful part still lies in the big dipper GPS bimodulus digit high accuracy synchronization time service equipment and the system that provide, only need install one set of time service equipment, through ethernet line (or optic fibre) connect current A equipment can, need not complicated wiring, the construction degree of difficulty is low.

Drawings

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

FIG. 1 is a schematic diagram of a Beidou/GPS dual-mode digital high-precision synchronous time service device of the present invention;

FIG. 2 is a schematic diagram of a high-precision network time service assembly according to the present invention;

fig. 3 is a schematic view of the radio frequency time service assembly of the present invention;

fig. 4 is a schematic diagram of the utility model discloses a big dipper/GPS bimodulus digital high accuracy synchronization time service system.

Detailed Description

Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below by referring to the drawings are exemplary intended for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, unless expressly stated or limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, e.g., as meaning permanently connected, detachably connected, or integral to one another; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood as a specific case by those skilled in the art.

In the present disclosure, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact between the first and second features, or may comprise contact between the first and second features not directly. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

As shown in fig. 1, a big dipper/GPS dual-mode digital high-precision synchronous time service device 1 of the present application includes: the system comprises a radio frequency time service component 12, a high-precision network time service component 11, a power supply component 14 and a UI component 13. The Beidou/GPS dual-mode digital high-precision synchronous time service equipment 1 receives satellite radio frequency signals such as Beidou, GPS, SBAS and the like through the satellite receiver component 2.

The radio frequency time service component 12 is configured to receive a radio frequency signal and perform radio frequency time service. The high-precision network time service component 11 is used for receiving radio frequency signals and performing network time service. The high-precision network time service component 11 mainly completes functions of Beidou signal receiving, time analysis and conversion, converts the received Beidou time information into standard PTP time information, and achieves a PTP + SyncE time service function. The radio frequency time service component 12 and the high-precision network time service component 11 complement each other, so that the time service requirement of the existing equipment is ensured, and the time service requirement of the subsequent upgrading equipment is also met. The power supply component 14 is connected to the radio frequency time service component 12 and the high-precision network time service component 11, and is used for providing electric energy for the Beidou/GPS dual-mode digital high-precision synchronous time service equipment 1. The UI component 13 is connected to the radio frequency time service component 12 and the high-precision network time service component 11, and is used for providing human-computer interaction, so as to facilitate the inquiry and setting of the device state by a user.

Specifically, the satellite receiver module 2 receives radio frequency time signals (beidou/GPS/SBAS, etc.), and transmits the radio frequency time signals to the high-precision network time service module 11 and the radio frequency time service module 12 for use. The high-precision network time service component 11 converts the radio frequency time service signal into digital information, and outputs the PTP + SyncE high-precision network time service information through internal protocol conversion. Meanwhile, the radio frequency time service component 12 receives the radio frequency time service signal, and converts the radio frequency time service signal into a radio frequency signal after active amplification and common division so as to output radio frequency time service information. And the power supply assembly 14 supplies power to the timing device. The UI component 13 ensures good man-machine interaction, and facilitates status query, information lookup, parameter setting and the like of the time service equipment. The Beidou/GPS dual-mode digital high-precision synchronous time service equipment 1 has two time service modes of high-precision network time service and radio frequency time service.

As shown in fig. 2, the high-precision network time service module 11 includes: two radio frequency receiver components I, an active amplification component I, a radio frequency signal-to-digital signal component 114, an FPGA component 116, an external interface component 117 and a core management component 115.

Wherein, two radio frequency receiver components are used for receiving radio frequency signals. One of the two rf receiver components is a first rf receiver component 111 and a second rf receiver component 112. The first radio frequency receiver component 111 and the second radio frequency receiver component 112 are primary and standby two-way radio frequency input interfaces, and do not affect the normal operation of the time service equipment when any one way radio frequency receiver component fails. And the active amplification component I is connected to the two radio frequency receiver components I and is used for enhancing the strength of the radio frequency signal. The first active amplification element is an active amplification element 113, which also has a dual channel backup function. The rf signal to digital signal conversion module 114 is connected to the first active amplification module, and is configured to convert the rf signal into a digital signal, so as to complete the function of converting the rf signal into the digital signal. The FPGA component 116 is configured to receive the digital signal and implement PTP protocol stack and SyncE functions. The information received by the FPGA component 116 is primarily Pulse Per Second (PPS) and time information (TOD). PPS is mainly used for phase synchronization, and TOD is mainly used for current time synchronization. The FPGA component 116 completes the analysis of the PPS and TOD signals, completes the standard IEEE1588V2 protocol conversion through the protocol processor, and packs the PPS + TOD information into an Ethernet standard interface. The external interface component 117 is connected to the FPGA component 116, and is used for providing a time service interface output function. The core management component 115 is connected to the first active amplification component, the rf signal to digital signal component 114, the FPGA component 116, and the external interface component 117, and is configured to provide device management functions.

As shown in fig. 3, the rf time service component 12 includes: two second radio frequency receiver components, a second active amplification component, and a divider component 124.

Wherein the two radio frequency receiver components are for receiving radio frequency signals. The two rf receiver components two are a first rf receiver component 121 and a second rf receiver component 122. The first radio frequency receiver component 121 and the second radio frequency receiver component 122 are primary and standby two-way radio frequency input interfaces, and do not affect the normal operation of the time service device when any one way radio frequency receiver component fails. And the second active amplification component is connected to the second two radio frequency receiver components and is used for enhancing the strength of the radio frequency signals. The second active amplifying element is an active amplifying element 123. The distributor component 124 is connected to the second active amplifying component for outputting the amplified rf signal. Preferably, the output is not less than 12 radio frequency signal outputs.

And the first radio frequency receiver component and the second radio frequency receiver component have the same functional module structure. Specifically, the first radio frequency receiver component and the second radio frequency receiver component both comprise: the low-noise amplifier comprises a first low-noise amplification module and a first power supply module.

The first low-noise amplification module is used for gaining the strength of the received radio-frequency signal. And the power supply module I is connected to the low-noise amplification module I to supply power to the low-noise amplification module I, so that the normal work of the whole receiver assembly is ensured.

The functional module structures of the first active amplification assembly and the second active amplification assembly are also the same. Specifically, the first active amplification component and the second active amplification component both comprise: the low-noise amplification module II, the band-pass filtering module, the dual-channel switching module and the power supply module II.

The second low-noise amplifying module is used for gaining the strength of the received radio frequency signal. And the band-pass filtering module is connected to the second low-noise amplifying module and is used for suppressing the radio-frequency signals outside the bandwidth. The dual-channel switching module is connected to the second low-noise amplification module and used for switching the primary and standby dual-channel radio-frequency signals, namely switching the connection relation between the first two radio-frequency receiver assemblies and the first active amplification assembly or switching the connection relation between the second two radio-frequency receiver assemblies and the second active amplification assembly according to conditions. And the power supply module II is connected to the low-noise amplification module II, the band-pass filtering module and the dual-channel switching module and supplies power to the modules.

In a preferred embodiment, the rf signal to digital signal component 114 comprises: the radio frequency receiving module, the radio frequency analysis module, the time service module, the external interface module and the power module III.

The radio frequency receiving module is used for receiving radio frequency signals. The radio frequency analysis module is connected to the radio frequency receiving module and used for analyzing the content of the radio frequency signal and converting the content of the radio frequency signal into a digital signal. The time service module is connected to the radio frequency analysis module and used for converting the digital signal into a high-precision network time service signal which is not limited to 1PPS + TOD information. The external interface module is connected to the time service module and used for outputting a network time service signal. It is understood that the external interface is not limited to UART, GPIO, USB, I2C, etc. And the power supply module III is connected to the radio frequency receiving module, the radio frequency analysis module, the time service module and the external interface module and supplies power to the modules.

As a preferred embodiment, the core management component 115 includes: the device comprises a detection function module, a control function module and a display function module.

The detection function module is used for detecting the state of the distributor assembly 124 connected with the time service equipment. The detection of the state of the distributor component 124 connected to the time service device refers to real-time monitoring of whether the lower level device is powered on or has a fault, and the purpose is to ensure normal time service for the lower level device and to report the fault in real time if the lower level device has a fault or has a power failure. The control function module is connected to the external interface component 117 and outputs the device dry contact point alarm information. The control function module is also connected to the active amplification component and controls the input of the radio frequency signal. The display function module is connected to the UI component 13, and is configured to display device information, including device basic information and parameter configuration.

As a preferred embodiment, the FPGA component 116 includes: the device comprises a protocol stack module and a phase-locked loop module.

The protocol stack module receives network time service information output by the digital signal module converted from the radio frequency signal, and realizes the complete PTP protocol stack function. The protocol stack module can be set to be in an OC (master clock) or BC (slave clock) mode according to a specific use environment, and the time service precision of the protocol stack module is less than or equal to 10ns. And the phase-locked loop module is connected to the protocol stack module and is used for realizing the high-precision time synchronization Ethernet technology. The PLL is provided, and the frequency error is less than or equal to 50ppb. Specifically, the protocol stack module mainly receives the network time service information, namely PPS and TO). PPS is mainly used for phase synchronization, and TOD is mainly used for current time synchronization. And after receiving the PPS, the protocol stack module tracks and locks the frequency phase in real time through the internal phase-locked loop module, and analyzes the received serial TOD information data. After being analyzed, the converted information is converted into a standard PTP protocol through a protocol conversion module and then is output through an Ethernet interface.

The external interface assembly 117 includes: a dry contact alarm module and a high-precision network time service output module.

The main contact alarm module is used for receiving main contact alarm information and performing double-power supply and double-radio frequency input abnormal alarm. And the high-precision network time service output module is used for providing a time service interface output function. The high-precision network time service output module is provided with 100M/1000M self-adaptive time service port output, an SFP optical port and RJ45 electric port output, and different time service interface requirements are met.

The divider assembly 124 includes a power detection module and an impedance matching module.

The power supply detection module is used for judging whether time service equipment is connected. The power supply detection module is used for judging whether time service equipment exists or not, namely detecting whether BBU equipment (described in detail below) and cascade time service terminal (slave) equipment are connected or not. The judgment is based on the online detection of the impedance, voltage and signal changes of the corresponding ports.

The impedance matching module is used for ensuring the lossless output of the radio frequency time service signal. Specifically, the impedance matching module amplifies, filters and shapes the radio frequency signal to ensure lossless output of the radio frequency model.

In a preferred embodiment, the power supply 14 includes a first power supply 141 and a second power supply 142.

The first power supply element 141 and the second power supply element 142 are identical in structure.

The first power supply element 141 and the second power supply element 142 each include: the power supply conversion module and the power supply isolation module.

The power conversion module reduces the input first voltage to a required second voltage. Specifically, the power conversion module converts the input 48V to the required 5V. The power isolation module ensures the stability when an abnormal power supply is input.

The UI component 13 includes: display screen functional module, button functional module and pilot lamp functional module.

The display screen functional module is matched with the key functional module for use and used for looking up states, parameter information, parameter configuration and the like. The indicator light functional module is used for displaying the basic operation state of the equipment.

The working principle of the high-precision network time service component 11 is as follows: the first rf receiver component 111 and the second rf receiver component 112 receive the rf timing signal, and transmit the received rf signal to the active amplification component 113 for signal amplification, noise reduction, and modulation. The rf signal to digital signal conversion module 114 demodulates and converts the processed rf time signal, and sends the converted digital signal to the core management module 115. The core management component 115 manages by the received digital signal, and displays device information, parameter information, and parameter settings in synchronization with the UI component 13. And transmits the processed time service information and frequency information to the FPGA component 116. The time service information and frequency received by the FPGA component 116 complete the whole high-precision network time service function through the complete PTP protocol stack, and output the high-precision SyncE frequency information to the external interface component 117. The external interface component 117 receives the alarm information of the core management component 115 to output a relay alarm, and simultaneously receives the external time service of the high-precision network time service information (PTP + SyncE) transmitted by the FPGA component 116, and completes the whole high-precision network time service process of the device.

The working principle of the radio frequency time service component 12 is as follows: the first rf receiver module 121 and the second rf receiver module 122 receive the rf timing signal, and transmit the received rf signal to the active amplification module 123 for signal amplification, noise reduction, and modulation. The distributor component 124 receives and outputs the processed radio frequency time service information, and completes the whole radio frequency time service process of the device.

As shown in fig. 4, the present application further discloses a big dipper/GPS dual-mode digital high-precision synchronous time service system, which includes: the device A comprises a device A, a plurality of BBU devices and the Beidou/GPS dual-mode digital high-precision synchronous time service device 1. The A equipment is connected to the Beidou/GPS dual-mode digital high-precision synchronous time service equipment 1, and the BBU equipment is connected to the A equipment.

Specifically, in the present application, the a device refers to an existing base station data transmission device of a base station, and the BBU device refers to an indoor baseband processing unit. The big Dipper/GPS dual-mode digital high-precision synchronous time service equipment 1 is connected with the equipment A through a gigabit Ethernet. The A equipment is connected with the BBU equipment through a gigabit Ethernet.

The 4G BBU equipment of the existing network only supports GPS satellite time service and does not support Beidou time service. The existing a device supports PTP functions. According to the Beidou/GPS dual-mode digital high-precision synchronous time service system, the A equipment is used as a bridge for clock transmission between the Beidou/GPS dual-mode digital high-precision synchronous time service equipment 1 and the BBU equipment, and a high-precision clock of the Beidou/GPS dual-mode digital high-precision synchronous time service equipment 1 is transmitted to the BBU equipment. The big dipper/GPS dual-mode digital high-precision synchronous time service system solves the problem of transformation of big dipper time service capacity by receiving a high-precision PTP clock signal of the device A, and is low in construction and maintenance cost.

The integral process of the Beidou/GPS dual-mode digital high-precision synchronous time service system comprises the following steps: the Beidou/GPS dual-mode digital high-precision synchronous time service equipment 1 receives radio frequency Beidou time service signals, and outputs PTP + SyncE high-precision network time service information after protocol conversion. The Beidou/GPS dual-mode digital high-precision synchronous time service equipment 1 serves as OC equipment and transmits high-precision network time service information (high-precision network time service-PTP + SyncE time service) to A equipment. The A device serves as a BC terminal to upwards receive the high-precision network time service information of the Beidou/GPS dual-mode digital high-precision synchronous time service device 1 and downwards send the high-precision network time service information to the BBU device. And the BBU equipment is used as a TC end to receive high-precision network time service information to complete the whole time service process. According to the Beidou/GPS dual-mode digital high-precision synchronous time service system, the PTP time service error is 2ns, the SyncE frequency error is-2 ppb, and the precision requirement far exceeds the requirement of a mobile communication standard.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It should be understood by those skilled in the art that the above embodiments do not limit the present invention in any way, and all technical solutions obtained by adopting equivalent replacement or equivalent transformation fall within the protection scope of the present invention.

Claims (10)

1. The utility model provides a big dipper GPS bimodulus digital high accuracy synchronization time service equipment which characterized in that contains:

the system comprises a radio frequency time service component, a high-precision network time service component, a power supply component and a UI component;

the power supply assembly is connected to the radio frequency time service assembly and the high-precision network time service assembly and provides electric energy for the Beidou/GPS dual-mode digital high-precision synchronous time service equipment;

the UI component is connected to the radio frequency time service component and the high-precision network time service component;

the high-precision network time service component comprises: the system comprises two radio frequency receiver assemblies I, an active amplification assembly I, a radio frequency signal-to-digital signal assembly, an FPGA assembly, an external interface assembly and a core management assembly;

the first active amplification component is connected to the first two radio frequency receiver components;

the radio frequency signal-to-digital signal component is connected to the first active amplification component;

the external interface component is connected to the FPGA component;

the core management component is connected to the first active amplification component, the radio-frequency signal-to-digital signal component, the FPGA component and the external interface component;

the radio frequency time service assembly comprises: two radio frequency receiver assemblies II, an active amplification assembly II and a distributor assembly;

the second active amplification component is connected to the second two radio frequency receiver components;

the distributor component is connected to the second active amplification component.

2. The Beidou/GPS dual-mode digital high-precision synchronous time service equipment according to claim 1,

the first radio frequency receiver component and the second radio frequency receiver component have the same structure, and both the first radio frequency receiver component and the second radio frequency receiver component comprise: the low-noise amplification module I and the power supply module I are connected;

the first power supply module is connected to the first low-noise amplification module.

3. The Beidou/GPS dual-mode digital high-precision synchronous time service equipment according to claim 2,

the first active amplification component and the second active amplification component have the same structure, and both the first active amplification component and the second active amplification component comprise: the low-noise amplification module II, the band-pass filtering module, the dual-channel switching module and the power supply module II are arranged in the power supply module;

the band-pass filtering module is connected to the second low-noise amplifying module;

the dual-channel switching module is connected to the second low-noise amplification module;

and the power supply module II is connected to the low-noise amplification module II, the band-pass filtering module and the dual-channel switching module.

4. The Beidou/GPS dual-mode digital high-precision synchronous time service equipment as claimed in claim 3,

the radio frequency signal-to-digital signal component comprises: the radio frequency receiving module, the radio frequency analyzing module, the time service module, the external interface module and the power supply module III;

the radio frequency analysis module is connected to the radio frequency receiving module;

the time service module is connected to the radio frequency analysis module;

the external interface module is connected to the time service module;

and the power supply module III is connected to the radio frequency receiving module, the radio frequency analysis module, the time service module and the external interface module.

5. The Beidou/GPS dual-mode digital high-precision synchronous time service equipment according to claim 4,

the core management component comprises: the device comprises a detection function module, a control function module and a display function module;

the detection function module is used for detecting the state of the distributor assembly connected with the time service equipment;

the control function module is connected to the external interface component and the active amplification component;

a display function module is connected to the UI component.

6. The Beidou/GPS dual-mode digital high-precision synchronous time service equipment as claimed in claim 5,

the FPGA component comprises: a protocol stack module and a phase-locked loop module;

the phase-locked loop module is connected to the protocol stack module.

7. The Beidou/GPS dual-mode digital high-precision synchronous time service equipment as claimed in claim 6,

the external interface assembly includes: the system comprises a dry contact point warning module and a high-precision network time service output module;

and the dry contact point warning module is connected to the high-precision network time service output module.

8. The Beidou/GPS dual-mode digital high-precision synchronous time service equipment according to claim 7,

the distributor assembly comprises a power supply detection module and an impedance matching module.

9. The Beidou/GPS dual-mode digital high-precision synchronous time service equipment according to claim 8,

the power supply assembly comprises a first power supply assembly and a second power supply assembly;

the first power supply assembly and the second power supply assembly are identical in structure;

the first and second power supply components each include: the power supply conversion module and the power supply isolation module;

the power isolation module is connected to the power conversion module.

10. A big dipper/GPS bimodulus digital high accuracy synchronization time service system, its characterized in that contains: the device A, a plurality of BBU devices and the Beidou/GPS dual-mode digital high-precision synchronous time service device of any one of claims 1 to 9;

the A equipment is connected to the Beidou/GPS dual-mode digital high-precision synchronous time service equipment;

a number of the BBU devices are connected to the A device.

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