CN220755065U - Base station energy consumption detection system - Google Patents

Abstract

The application discloses base station energy consumption detecting system includes: the system comprises energy consumption evaluation equipment, energy consumption inspection equipment, networking equipment and instrument equipment, wherein the energy consumption inspection equipment is connected with a power supply, the energy consumption inspection equipment is also connected with base station equipment to be tested, the networking equipment is connected with the base station equipment to be tested, and the instrument equipment is connected with the base station equipment to be tested; the energy consumption checking device, the networking device, the instrument device and the base station to-be-tested device are all in communication connection with the energy consumption evaluation device. The method and the device can improve the efficiency of base station energy consumption detection.

Description

Base station energy consumption detection system

Technical Field

The application relates to the technical field of communication, in particular to a base station energy consumption detection system.

Background

Currently, base station energy consumption detection generally depends on a large amount of manpower. Specifically, the to-be-tested equipment of the base station is usually connected with measuring equipment such as a voltmeter, an ammeter and a spectrometer, after a test environment is built according to test requirements, the measuring data of each measuring equipment are manually observed to record base station energy consumption data, and whether the base station energy consumption is normal or not is judged. The number of the base station measuring devices is usually large, and the base station energy consumption data is recorded by completely manually observing the measurement data of each measuring device, so that the base station energy consumption detection efficiency is low.

Disclosure of Invention

The embodiment of the application provides a base station data detection system, which aims to solve the problem of lower base station data detection efficiency in the prior art.

In order to solve the technical problems, the present application is so implemented;

the embodiment of the application provides a base station energy consumption detection system, which comprises: the system comprises energy consumption evaluation equipment, energy consumption inspection equipment, networking equipment and instrument equipment, wherein the energy consumption inspection equipment is connected with a power supply, the energy consumption inspection equipment is also connected with base station equipment to be tested, the networking equipment is connected with the base station equipment to be tested, and the instrument equipment is connected with the base station equipment to be tested;

the energy consumption checking device, the networking device, the instrument device and the base station to-be-tested device are all in communication connection with the energy consumption evaluation device.

According to the embodiment of the application, the base station data detection system comprises energy consumption assessment equipment, energy consumption inspection equipment, networking equipment and instrument equipment. The energy consumption detection equipment is connected with the power supply, and is also connected with the base station equipment to be detected, so that the energy consumption detection equipment can supply power to the base station equipment to be detected and can detect energy consumption data of the base station equipment to be detected; the energy consumption detection equipment is in communication connection with the energy consumption evaluation equipment, so that the energy consumption detection equipment can send the energy consumption data of the equipment to be detected of the base station to the energy consumption evaluation equipment, and the energy consumption evaluation equipment can evaluate the energy consumption of the equipment to be detected of the base station based on the energy consumption data.

Drawings

Fig. 1 is a schematic diagram of a base station energy consumption detection system according to an embodiment of the present application;

fig. 2 is a schematic diagram of an energy consumption test apparatus according to an embodiment of the present application.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are some, but not all, of the embodiments of the present application. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.

Fig. 1 is a schematic diagram of a base station energy consumption detection system according to an embodiment of the present application.

As shown in fig. 1, the base station data detection system includes: the energy consumption evaluation device 1, the energy consumption inspection device 2, the networking device 3 and the instrument device, wherein the energy consumption inspection device 2 is connected with a power supply, the energy consumption inspection device 2 is also connected with base station equipment to be tested, the networking device 3 is connected with the base station equipment to be tested, and the instrument device is connected with the base station equipment to be tested;

the energy consumption test equipment 2, the networking equipment 3, the instrument equipment and the equipment to be tested of the base station are all in communication connection with the energy consumption evaluation equipment 1.

The base station device under test may generally include a remote radio unit (Remote Radio Unit, RRU), an indoor baseband processing unit (Building Base band Unit, BBU), a radio power amplifier (Radio Frequency Power Amplifier, RFPA), and the like. Currently, some base station devices further include an active antenna unit (Active Antenna Unit, AAU), where the AAU is a base station device that merges RRU and antenna units, and in the case that the base station device includes an AAU, the base station device to be tested in the embodiment of the present application may further include an AAU.

The energy consumption test equipment 2 is connected with a power supply, and the power supply can be 220V commercial power. The energy consumption detection equipment 2 is also connected with the equipment to be detected of the base station, so that a power supply can transmit electric energy to the equipment to be detected of the base station through the energy consumption detection equipment 2. The base station to be tested equipment can be a plurality of base station to be tested equipment or one base station to be tested equipment, and the number of the base station to be tested equipment is not limited in the embodiment of the application. The energy consumption test device 2 comprises a detection unit for detecting energy consumption data, such as a supply voltage and a supply current, of a device to be tested of the base station.

The networking device 3 is connected with a device to be tested of the base station, and specifically, the networking device 3 can be connected with an RRU or an AAU of the base station. The base station comprises a plurality of channels, and the radio frequency signals can be input into the RRU or the AAU through the plurality of channels, and can also be output through the plurality of channels. The networking device 3 in the embodiment of the present application is connected to an RRU or an AAU of a base station, where the networking device 3 is mainly configured to communicate any one of multiple channels with an instrument device. Taking as an example that the meter device includes a spectrometer (also referred to as a spectrum analyzer), the networking device 3 communicates any one of a plurality of channels with the spectrometer, so that only one spectrometer needs to be provided, and by switching different channels to communicate with the one spectrometer, the output power of each channel, the error vector magnitude (Error Vector Magnitude, EVM) and the like can be detected. Therefore, the networking unit is arranged, so that the instrument equipment resources can be effectively saved.

In some embodiments, the meter device may include a plurality of meter devices. The instrument equipment in the application is connected with the base station equipment to be tested, and can be that part of the instrument equipment is connected with the base station equipment to be tested through the networking unit, and the other part of the instrument equipment is directly connected with the base station equipment to be tested. As an example, taking an instrument device including a spectrometer and an oscilloscope as an example, the spectrometer may be connected to the base station device under test through a networking unit, and the oscilloscope may be directly connected to the base station device under test. The oscillograph is directly connected with the equipment to be tested of the base station, mainly the oscillograph is connected with the BBU, at present, the base station is required to be dynamically regulated to enable the base station to be in different energy-saving states, the oscillograph is connected with the BBU, and whether the dynamic regulation of the base station reaches a preset index can be judged by reading the waveform of the oscillograph.

The energy consumption evaluation device 1 is a device capable of running a client. The energy consumption evaluation device 1 is connected with the energy consumption test device 2, so that the energy consumption evaluation device 1 can acquire the energy consumption data of the base station device to be tested from the energy consumption test device 2. The energy consumption evaluation device 1 is connected to the networking device 3 so that the energy consumption evaluation device 1 can control the networking device 3 to communicate any one of the plurality of channels with a part of the meter devices. The energy consumption evaluation device 1 is connected to the meter device such that the energy consumption evaluation device 1 can read the measurement data of the meter device and can read the measurement data of the meter device at a certain time period, and in particular, the energy consumption evaluation device 1 can read the measurement data of the corresponding meter device through the communication address of the meter device. The energy consumption evaluation device 1 is connected with the base station to-be-measured device, so that the energy consumption evaluation device 1 can acquire information of the base station to-be-measured device, such as the transmitting power of the base station, the energy saving state of the base station, and the like.

In some embodiments, the energy consumption testing device 2, the networking device 3, the meter device, and the base station device under test may be communicatively connected to the energy consumption assessment device 1 via a Hub (Hub).

The energy consumption evaluation apparatus 1 of the embodiment of the present application is also capable of: according to the set index, verifying whether the energy consumption data of the equipment to be tested of the base station and the measurement data of the instrument equipment are abnormal or not; in the verification process, if the data is abnormal, the judgment process can be interrupted and an alarm is given; outputting the data statistic value in the verification process after the verification is finished and outputting the change condition of the energy consumption of the base station along with the change of time; remote operation is supported.

It should be noted that, in the embodiment of the present application, the test environment of the base station may be automatically configured according to a preset rule based on the local maintenance terminal (Local Maintenance Terminal, LMT), for example, state parameters of the base station may be automatically configured, so that the base station may be in different states such as full-load power consumption, 50% load power consumption, idle power consumption, sub-frame silence, channel silence, downlink power control, macro-micro cooperative dormancy, shallow sleep or deep sleep repair, so that the energy consumption evaluation device 1 may be capable of detecting energy consumption of the base station to be tested device in different states, and the meter device may be capable of detecting output power of the base station to be tested device in different states, and base station performance data such as EVM.

Based on the above setting, the base station energy consumption detection system in the embodiment of the present application can implement automation of energy consumption detection, and the energy consumption evaluation device 1 can evaluate the energy consumption of the base station to-be-detected device based on the energy consumption data, so that the energy consumption data of the base station is recorded without manually observing the measurement data of each measurement device, thereby improving the detection efficiency of the base station energy consumption.

Optionally, as shown in fig. 2, the base station to-be-detected device includes N to-be-detected devices, where the energy consumption detection device 2 includes N detection units 21 and N control units 22, a first end of each N detection unit 21 is connected to the power supply, a second end of each N detection unit 21 is connected to a first end of each N control unit 22, a second end of each N control unit 22 is connected to each N to-be-detected devices, and N is an integer greater than 1;

wherein each of the N-way control units 22 includes a pass state and a break state.

In this embodiment, the N-way control unit 22 is disposed between the N-way detection unit 21 and N base station devices under test, each device under test being connected to a power supply through a corresponding control unit and detection device. The N-way control unit 22 includes a path state and an off state, and is capable of controlling whether to supply power to each base station device to be tested and detecting energy consumption of each base station device to be tested by controlling the state of the control unit corresponding to each base station device to be tested.

As an example, assume that a first end of the first detection unit is connected to a power supply, a second end of the first detection unit is connected to a first end of the first control unit, a second end of the first control unit is connected to the base station RFPA, the first control unit is in a path state, the first detection unit detects energy consumption data of the RFPA, and the first control unit is in an off state, and the first detection unit stops detecting the energy consumption data of the RFPA.

In this embodiment of the application, through above-mentioned setting, whether can control to each base station equipment to be tested according to the test demand and whether detect the energy consumption of each base station equipment to be tested, so, need not the manual work many times with each base station equipment to be tested with energy consumption supply examine the unit and connect or disconnect, can improve efficiency and the flexibility to the base station energy consumption detection.

Optionally, the energy consumption test equipment 2 further comprises a main control equipment 23 and/or an input/output equipment 24;

the third end of the N-way detecting unit 21 is connected with a remote device through the main control device 23, and the third end of the N-way controlling unit 22 is also connected with the remote device through the main control device 23,

and/or the number of the groups of groups,

the fourth terminal of the N-way detecting unit 21 is connected to the input/output device 24, and the fourth terminal of the N-way control unit 22 is also connected to the input/output device 24.

In this embodiment, the third end of the N-way detecting unit 21 is connected to a remote device through the master control device 23, so that the energy consumption data detected by each way of detecting unit can be reported to the remote device through the master control device 23, and the remote device is a host computer. The third terminal of the N-way control unit 22 is also connected to a remote device through the master control device 23, so that the remote device can control the state (on state or off state) in which each way control unit is located through the master control device 23.

The fourth terminal of the N-way detecting unit 21 is connected to an input-output device 24, and the representation of the input-output device 24 is, for example, a display screen. By directly providing the fourth terminal of the N-way detecting unit 21 to be connected to the input-output device 24, the energy consumption data detected by each way of detecting unit can be directly output through the input-output device 24. By directly providing the fourth terminal of the N-way control unit 22 to be connected to the input-output device 24, the input-output device 24 can directly control the state (the on-state or the off-state) in which each way control unit is located.

The embodiment of the application further comprises the main control equipment 23 and/or the input/output equipment 24 by setting the energy consumption test equipment 2, so that the main control equipment 23 and/or the input/output equipment 24 can acquire the energy consumption data of each base station to-be-tested equipment and control the state of each path of control unit, thus, the cost can be saved by setting the main control equipment 23 and/or the input/output equipment 24 to integrate multiple functions, and the occupation space of the base station detection system can be reduced,

currently, in the technology related to the present application, conventional base station energy consumption detection generally calculates the instantaneous energy consumption of a device to be tested of a base station according to the instantaneous voltage and the instantaneous current, and it is difficult to accurately determine the long-term energy consumption of the device to be tested of the base station according to the instantaneous energy consumption.

Based on the above, the embodiment of the present application may determine, by the master control device 23 or the energy consumption evaluation device 1, the long-term energy consumption of the base station device under test in a certain period of time. The energy consumption detection parameter is configured by a remote device (e.g., a host computer), the energy consumption evaluation device 1, or the input-output device 24. The remote device, the energy consumption evaluation device 1, or the input/output device 24 sends the energy consumption detection parameters to the N-way control unit 22, and the N-way control unit 22 controls the corresponding N-way detection unit 21 to detect the power supply voltages and power supply currents of the corresponding N devices to be detected according to the energy consumption detection parameters, where the energy consumption detection parameters include a detection frequency F, a detection period T, and the like. The detection frequency F may be detected once every second or every minute, the power supply voltage detected by each detection unit is denoted as V, the power supply current is denoted as I, each detection unit may transmit the power supply voltage V and the power supply current I detected each time to the energy consumption evaluation device 1 or the master device 23, and the energy consumption evaluation device 1 or the master device 23 determines the power consumption (i.e., energy consumption) of each base station device under test in the period T according to the following formulas 1 and 2. The master device 23 may be a single chip microcomputer, and if the power consumption of each base station to-be-measured device in the time period T is determined for the master device 23, the master device 23 may send the determined power consumption to the energy consumption evaluation device 1 after determining the power consumption.

n＝T÷F (2)

Wherein P is the electricity consumption in the time period T, V _n For the nth detected supply voltage, I _n For the nth detected supply current, F is the detection frequency.

According to the embodiment of the application, the energy consumption detection parameters are configured through the remote equipment (such as an upper computer), the energy consumption evaluation equipment 1 or the input/output equipment 24, so that the N-way detection unit 21 can detect the voltage V and the current I of N base station equipment to be detected at high frequency, and the electricity consumption of the N base station equipment to be detected in the time period T can be accurately calculated through a data integration method based on the voltage V, the current I, the detection frequency F and the detection time period T.

Optionally, the energy consumption test device 2 further includes a voltage transformation device 25 and an N-way power output unit 26, one end of the N-way power output unit 26 is connected with a power supply through the voltage transformation device 25, and the other end of the N-way power output unit 26 is connected with the first end of the N-way detection unit 21 one by one.

In this embodiment, one end of the N-way power output unit 26 is connected to a power supply through a voltage transformation device 25, so that the output voltage of the N-way power output unit 26 can be adjusted through the voltage transformation device 25. The other end of the N-way power output unit 26 is connected to the first ends of the N-way detection units 21 one by one, so that by adjusting the output voltage of the N-way power output unit 26, the power supply voltage of the power consumption detection equipment 2 to the N base stations to be detected can be adjusted.

According to the embodiment of the application, the voltage transformation equipment 25 is arranged, so that the power supply voltage of the equipment to be detected of the N base stations can be flexibly adjusted, and the flexibility of the base station energy consumption detection system can be improved.

Optionally, the voltage transformation device 25 includes a switching power supply and a voltage regulator, and one end of the N-path power output unit 26 is connected to the power supply through the switching power supply, and the switching power supply is further connected to the voltage regulator.

In this embodiment, the voltage transformation device 25 comprises a switching power supply and a voltage regulator. The switching power supply is, for example, a 48v switching power supply, and the power supply is connected with one end of the N-way power supply output unit 26 through the switching power supply, so that the N-way power supply output unit 26 outputs 48v power under default conditions, and the output voltage of the N-way power supply output unit 26 can be adjusted through a voltage adjusting piece (for example, a knob), and the adjusting range can be set according to test requirements, for example, the adjusting range can be 0 v-50 v.

According to the embodiment of the application, the voltage transformation equipment 25 comprises a switching power supply and a voltage regulating piece, so that the output voltage of the N-path power supply output unit 26 can be flexibly regulated, and the power supply voltage of equipment to be detected of N base stations can be flexibly regulated; and moreover, the switching power supply and the voltage regulating piece are common equipment, and the operation is simple and feasible.

Optionally, the detection system includes a plurality of instrument devices, the networking device 3 includes an array switch, the base station to-be-detected device includes M channel interfaces, one end of the array switch is connected with any one of the M channel interfaces, the other end of the array switch is connected with at least one instrument device of the plurality of instrument devices, and M is an integer greater than 1.

In this embodiment, the base station to-be-detected device includes M channel interfaces, where the M channel interfaces are disposed in an AAU or an RRU of the base station, and each channel interface corresponds to one channel of the base station.

The array switch, which is also referred to as a matrix switch or a switching matrix, enables any of the M channel interfaces to be connected to at least one meter device based on the instructions of the energy consumption evaluation device 1 by providing the array switch. In the case where a certain channel interface is connected to at least one meter device, a channel corresponding to the channel interface is communicated with at least one meter device, and the at least one meter device can test performance data of the channel communicated therewith. Taking at least one meter device including a spectrometer as an example, the array switch communicates any one of the plurality of channels with the spectrometer, so that only one spectrometer needs to be provided, and different channels are switched to communicate with the one spectrometer through the array switch by an instruction of the energy consumption evaluation device 1, that is, performance data of each channel can be detected. Therefore, the networking unit comprises the array switch, so that the instrument equipment resources can be effectively saved.

Optionally, the networking device 3 further includes M attenuators, where the M attenuators are connected to the M channel interfaces one by one, and one end of the array switch is connected to any channel interface through an attenuator corresponding to the any channel interface.

In this embodiment, the M attenuators are connected to the M channel interfaces one by one, and one end of the array switch is connected to any channel interface through the attenuator corresponding to any channel interface, so that the downlink signal output by any channel interface needs to be attenuated by the attenuator, and the power of the downlink signal output by any channel interface can be effectively reduced, so that the power of the downlink signal can be matched with the testable range of at least one meter device, and the at least one meter device is a meter device connected to the channel interface outputting the downlink signal. The attenuation value of the attenuator can be configured based on the testable range, and specifically, the testable range of the energy consumption evaluation device 1 sends a configuration instruction to the attenuator.

According to the embodiment of the application, the M attenuators are arranged to be connected with the M channel interfaces one by one, and one end of the array switch is connected with any channel interface through the attenuator corresponding to any channel interface, so that signals output by any channel to the instrument equipment are in the testable range of the instrument equipment, and the reliability of the base station energy consumption detection system is improved.

Optionally, the networking device 3 further includes a power divider, the power divider includes at least a first output end and a second output end, the meter device includes at least a first meter device and a second meter device, the other end of the array switch is connected with the first meter device through the first output end of the power divider, and the other end of the array switch is connected with the second meter device through the second output end of the power divider.

According to the embodiment of the utility model, the power divider is arranged, so that any one of M channel interfaces can be at least connected with the first instrument equipment and the second instrument equipment through the networking equipment 3, namely any one of the M channel interfaces can be connected with different instrument equipment through the networking equipment 3, and different performance test data of any channel can be acquired through different instrument equipment; by acquiring different performance data of any channel, the performance test data of the base station energy consumption detection system can be enriched, and the base station energy consumption detection effect can be improved.

Optionally, the base station energy consumption detection system further includes a signal transmitter, the networking device 3 further includes a circulator, the first instrument device is a spectrometer, a first output end of the power divider is connected with the spectrometer through the circulator, and a first output end of the power divider is further connected with the signal transmitter through the circulator.

In this embodiment, the first output end of the power divider is connected to the spectrometer through the circulator, and the first output end of the power divider is further connected to the signal transmitter through the circulator, where the circulator is configured to isolate an uplink signal sent by the signal transmitter to the base station from a downlink signal sent by the base station to the spectrometer.

The signal transmitter can transmit an uplink signal to any channel through the power divider and the array switch, the base station can process the uplink signal after receiving the uplink signal, and the energy consumption evaluation device 1 evaluates the relevant performance data of any channel based on the processing result; the spectrometer detects the downlink signal emitted by any channel, and the energy consumption evaluation device 1 evaluates the relevant performance data of any channel based on the spectrometer test data, so that the performance test data of the base station energy consumption detection system can be enriched through the arrangement, and the base station energy consumption detection effect can be improved.

The optional base station energy consumption detection system further comprises a test terminal, the second instrument equipment is a terminal state monitoring instrument, and the second output end of the power divider is connected with the terminal state monitoring instrument through the test terminal.

In some embodiments, for some functions of the base station, it is required to determine the performance of the base station to-be-tested device through the access condition of a test terminal (User Equipment, UE), specifically, the energy consumption evaluation device 1 monitors the access condition of the test terminal based on the terminal state monitoring instrument, and determines the performance of the base station to-be-tested device based on the access condition of the test terminal.

The base station energy consumption detection system further comprises a test terminal, and the second instrument equipment is a terminal state monitoring instrument, so that performance test data of the base station energy consumption detection system can be enriched, and the base station energy consumption detection effect can be improved.

In order to more clearly understand the technical solutions of the embodiments of the present application, specific examples are provided below to illustrate the base station energy consumption detection steps of the present application.

Step 1, system configuration: configuring a detection environment comprising instrument types and instrument addresses, a switch matrix, basic parameters of an energy consumption detection unit, advanced parameters of a test case and the like, and realizing effective connection of all modules in a system;

step 1, task configuration: configuring information of a base station to be evaluated, indexes to be evaluated, execution parameters of the indexes and a time period for carrying out electricity consumption statistics;

step 3, detection execution:

(1) Setting the transmitting power of the base station through the BBU and the LTM, and transmitting a full-power configuration data source to the base station through the BBU, namely transmitting the full-power configuration data source according to the full power by the base station.

(2) And controlling the switching of the switch matrix to select the channel to be tested.

(3) Setting a power template on the spectrometer to read the output power of the channel

(4) Setting EVM template on spectrum instrument to read EVM of the channel

(5) Judging whether the equipment parameters are normal or not according to the parameter information set in the step 2

(6) The energy consumption detection unit detects voltage and current data on each power supply output channel in real time

(7) The main control device 23 calculates the instantaneous power consumption value according to the voltage and current data in real time and outputs the instantaneous power consumption value through the touch input/output device 24 or the power consumption evaluation device 1

(8) The main control device 23 or the energy consumption evaluation device 1 determines the amount of electricity used for a period of time, and the energy consumption evaluation device 1 and the input-output device 24 output the amount of electricity used.

And step 4, finishing the detection. And performing a preview function of the task data which has been detected, and selecting a format of the output report.

And 5, generating detection results of task execution time, task number, use cases and the like.

The above detailed description should not be taken as limiting the scope of the present disclosure. It will be apparent to those skilled in the art that various modifications, combinations, sub-combinations and alternatives are possible, depending on design requirements and other factors. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the present disclosure are intended to be included within the scope of the present disclosure.

Claims (10)

1. A base station energy consumption detection system, comprising: the system comprises energy consumption evaluation equipment, energy consumption inspection equipment, networking equipment and instrument equipment, wherein the energy consumption inspection equipment is connected with a power supply, the energy consumption inspection equipment is also connected with base station equipment to be tested, the networking equipment is connected with the base station equipment to be tested, and the instrument equipment is connected with the base station equipment to be tested;

the energy consumption checking device, the networking device, the instrument device and the base station to-be-tested device are all in communication connection with the energy consumption evaluation device.

2. The base station energy consumption detection system according to claim 1, wherein the base station equipment to be detected comprises N pieces of equipment to be detected, the energy consumption detection equipment comprises N pieces of detection units and N pieces of control units, a first end of each N piece of detection unit is connected with the power supply, a second end of each N piece of detection unit is connected with a first end of each N piece of control unit, a second end of each N piece of control unit is connected with each N pieces of equipment to be detected, and N is an integer greater than 1;

each of the N paths of control units comprises a path state and an open circuit state.

3. The base station energy consumption detection system according to claim 2, wherein the energy consumption detection device further comprises a master control device and/or an input-output device;

the third end of the N-way detection unit is connected with the remote equipment through the main control equipment, and the third end of the N-way control unit is also connected with the remote equipment through the main control equipment,

and/or the number of the groups of groups,

the fourth end of the N-way detection unit is connected with the input and output equipment, and the fourth end of the N-way control unit is also connected with the input and output equipment.

4. The base station energy consumption detection system according to claim 2, wherein the energy consumption detection device further comprises a voltage transformation device and N power output units, one end of each N power output unit is connected with a power supply through the voltage transformation device, and the other end of each N power output unit is connected with the first end of each N detection units one by one.

5. The base station energy consumption detection system according to claim 4, wherein the voltage transformation device comprises a switching power supply and a voltage regulating member, one end of the N-way power supply output unit is connected with a power supply through the switching power supply, and the switching power supply is further connected with the voltage regulating member.

6. The base station energy consumption detection system according to claim 1, wherein the detection system comprises a plurality of meter devices, the networking device comprises an array switch, the base station device under test comprises M channel interfaces, one end of the array switch is connected with any one of the M channel interfaces, the other end of the array switch is connected with at least one meter device of the plurality of meter devices, and M is an integer greater than 1.

7. The base station energy consumption detection system according to claim 6, wherein the networking device further comprises M attenuators, the M attenuators are connected with the M channel interfaces one by one, and one end of the array switch is connected with any channel interface through the corresponding attenuator of the any channel interface.

8. The base station energy consumption detection system according to claim 6, wherein the networking device further comprises a power divider, the power divider comprises at least a first output end and a second output end, the meter device comprises at least a first meter device and a second meter device, the other end of the array switch is connected with the first meter device through the first output end of the power divider, and the other end of the array switch is connected with the second meter device through the second output end of the power divider.

9. The base station energy consumption detection system of claim 8, further comprising a signal transmitter, wherein the networking device further comprises a circulator, wherein the first meter device is a spectrometer, wherein the first output of the power divider is connected to the spectrometer through the circulator, and wherein the first output of the power divider is further connected to the signal transmitter through the circulator.

10. The base station energy consumption detection system according to claim 8, further comprising a test terminal, wherein the second meter device is a terminal status monitor, and wherein the second output terminal of the power divider is connected to the terminal status monitor through the test terminal.