CN105824332B - Intelligent monitoring method and system - Google Patents

Abstract

The invention discloses an intelligent monitoring method and a system, wherein the system comprises an intelligent monitoring device and a monitoring agent device connected with the intelligent monitoring device; the intelligent monitoring device is used for receiving the current temperature and the current power consumption obtained by detecting the nodes to be monitored in the electronic equipment by the monitoring agent device; adjusting the rotating speed of the fan to control the temperature of the node to be monitored according to the current temperature of the node to be monitored; if the current power consumption of the node to be monitored is judged to be larger than the preset maximum power consumption, a first power-down instruction is sent to the monitoring agent device; the monitoring agent device is used for detecting the current temperature and the current power consumption of the node to be monitored and reporting the current temperature and the current power consumption to the intelligent monitoring device; and receiving a first power-down instruction from the intelligent monitoring device, and executing power-down operation on the node to be monitored. The invention at least solves the problem that the intelligent monitoring of the switch system can not be realized in the related technology.

Description

Intelligent monitoring method and system

Technical Field

The invention relates to the field of communication, in particular to an intelligent monitoring method and system.

Background

In recent years, with the rapid development of the Internet, an IP (Internet Protocol) network has become an indispensable tool in people's daily work and life. Meanwhile, due to the advantages of low cost, easy deployment and the like of the Ethernet technology, the proportion of the Ethernet technology in the construction of a metropolitan area network is gradually increased, the network scale is also continuously enlarged, a large number of Ethernet switch products are deployed, and no modern high-end switch is a large-scale rack product and usually bears the transmission task of a core node in a certain area through stacking and gathering, so that the system stability and the reliability are particularly important.

For modern high-end switches, from the perspective of the complete machine or each single board, very effective management and monitoring of system performance are required. Due to the large scale of the system and the high transmission rate, the power consumption and heat dissipation problems become more prominent than other devices. Moreover, the requirements of each function board on the stability and reliability of the system operation state become more severe. Therefore, a reliable system intelligent monitoring scheme is the most basic element for ensuring the system to operate normally.

Aiming at the problem of realizing intelligent monitoring of a switch system, an effective solution is not provided at present.

Disclosure of Invention

The invention provides an intelligent monitoring method and system, which at least solve the problem that the intelligent monitoring of a switch system cannot be realized in the related technology.

According to one aspect of the invention, an intelligent monitoring system is provided, which is applied to electronic equipment and comprises an intelligent monitoring device and a monitoring agent device connected with the intelligent monitoring device; the intelligent monitoring device is used for receiving the current temperature and the current power consumption obtained by detecting the nodes to be monitored in the electronic equipment by the monitoring agent device; adjusting the rotating speed of the fan to control the temperature of the node to be monitored according to the current temperature of the node to be monitored; when the current power consumption of the node to be monitored is judged to be larger than the preset maximum power consumption, a first power-down instruction is sent to the monitoring agent device; the monitoring agent device is used for detecting the current temperature and the current power consumption of the node to be monitored and reporting the current temperature and the current power consumption to the intelligent monitoring device; and receiving a first power-down instruction from the intelligent monitoring device, and executing power-down operation on the node to be monitored.

Preferably, the intelligent monitoring device adjusts the rotating speed of the fan to control the temperature of the node to be monitored according to the current temperature of the node to be monitored by executing the following steps: when the current temperature of the node to be monitored is greater than a first preset value, first speed regulation information is sent to the fan, and the first speed regulation information is used for indicating the fan to increase the rotating speed; and if the current temperature of the node to be monitored is less than a second preset value, sending second speed regulation information to the fan, wherein the second speed regulation information is used for indicating the fan to reduce the rotating speed.

Preferably, the intelligent monitoring device is further used for obtaining the maximum output power of the power supply; and if the current power consumption of the node to be monitored is greater than the maximum output power of the power supply, sending a second power-off instruction to the power supply so that the power supply executes power-off operation according to the second power-off instruction.

Preferably, the intelligent monitoring device is further configured to send an alarm signal when it is determined that the current power consumption of the node to be monitored is greater than a preset maximum power consumption.

Preferably, the monitoring agent device is further configured to read a preset voltage on the node to be monitored, and report the preset voltage to the intelligent monitoring device; the intelligent monitoring device is also used for receiving the preset voltage from the monitoring agent device; and obtaining the maximum power consumption of the node to be monitored corresponding to the preset voltage according to the mapping relation between the voltage and the power consumption of the node to be monitored.

Preferably, the intelligent monitoring device is further used for obtaining the maximum output power of the power supply; when the maximum output power of the power supply is not less than the maximum power consumption of the node to be monitored, sending a power-on instruction to the monitoring agent device; and the monitoring agent device is also used for receiving the power-on instruction from the intelligent monitoring device and executing power-on operation on the node to be monitored.

Preferably, the intelligent monitoring device is also used for receiving fault information from the fan; and sending a first power-down instruction to the monitoring agent device according to the fault information.

Preferably, the monitoring agent device is disposed on the node to be monitored.

According to another aspect of the present invention, there is provided an intelligent monitoring method applied to an electronic device, including: receiving the current temperature and the current power consumption obtained by detecting the nodes to be monitored in the electronic equipment from the monitoring agent device; adjusting the rotating speed of the fan to control the temperature of the node to be monitored according to the current temperature of the node to be monitored; and if the current power consumption of the node to be monitored is judged to be larger than the preset maximum power consumption, sending a first power-down instruction to the monitoring agent device.

Preferably, according to the current temperature of the node to be monitored, adjusting the rotation speed of the fan to control the temperature of the node to be monitored comprises: if the current temperature of the node to be monitored is greater than a first preset value, first speed regulation information is sent to the fan, and the first speed regulation information is used for indicating the fan to increase the rotating speed; and if the current temperature of the node to be monitored is less than a second preset value, sending second speed regulation information to the fan, wherein the second speed regulation information is used for indicating the fan to reduce the rotating speed.

According to another aspect of the present invention, there is provided an intelligent monitoring method applied to an electronic device, including: detecting the current temperature and the current power consumption of a node to be monitored, and reporting the current temperature and the current power consumption to an intelligent monitoring device; and under the condition that the intelligent monitoring device judges that the current power consumption of the node to be monitored is larger than the preset maximum power consumption, receiving a first power-down instruction from the intelligent monitoring device, and executing power-down operation on the node to be monitored.

According to the invention, the technical scheme that the current temperature and the current power consumption obtained by detecting the node to be monitored in the electronic equipment by the receiving monitoring agent device are adopted, the rotating speed of the fan is adjusted according to the current temperature of the node to be monitored so as to control the temperature of the node to be monitored, and if the current power consumption of the node to be monitored is judged to be larger than the preset maximum power consumption, a first power-off instruction is sent to the monitoring agent device is adopted, so that the problem that the intelligent monitoring of a switch system cannot be realized in the related technology is solved, and the effect of intelligently monitoring the interior of the electronic equipment is further achieved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the drawings:

FIG. 1 is a schematic diagram of an intelligent monitoring system according to an embodiment of the invention;

FIG. 2 is a schematic flow diagram of an intelligent monitoring method according to an embodiment of the invention;

FIG. 3 is a schematic flow chart diagram of another intelligent monitoring method according to an embodiment of the invention;

FIG. 4 is a schematic diagram of a logical structure of another intelligent monitoring system according to an embodiment of the invention;

FIG. 5 is a schematic diagram of the intelligent monitoring system according to the preferred embodiment of the invention;

FIG. 6 is a schematic diagram of a system power-up implemented by a monitoring agent unit according to the present invention;

fig. 7 is a schematic diagram of a power-on control flow of an intelligent monitoring unit implemented in accordance with the present invention.

Detailed Description

The invention will be described in detail hereinafter with reference to the accompanying drawings in conjunction with embodiments. It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict.

In this embodiment, an intelligent monitoring system is provided, which is applied to an electronic device, and fig. 1 is a schematic structural diagram of an intelligent monitoring system according to an embodiment of the present invention, as shown in fig. 1, including an intelligent monitoring apparatus and a monitoring agent apparatus connected to the intelligent monitoring apparatus; wherein,

the intelligent monitoring device is used for receiving the current temperature and the current power consumption obtained by the monitoring agent device detecting the nodes to be monitored in the electronic equipment; adjusting the rotating speed of the fan to control the temperature of the node to be monitored according to the current temperature of the node to be monitored; when the current power consumption of the node to be monitored is judged to be larger than the preset maximum power consumption, a first power-down instruction is sent to the monitoring agent device;

the monitoring agent device is used for detecting the current temperature and the current power consumption of the node to be monitored and reporting the current temperature and the current power consumption to the intelligent monitoring device; and receiving a first power-down instruction from the intelligent monitoring device, and executing power-down operation on the node to be monitored.

Through the steps, the intelligent monitoring device adjusts the rotating speed of the fan to control the temperature of the node to be monitored according to the current temperature and the current power consumption of the node to be monitored, which are obtained from the monitoring agent device, and sends a first power-down instruction to the monitoring agent device if the current power consumption of the node to be monitored is judged to be larger than the preset maximum power consumption, so that the problem that intelligent monitoring of a switch system cannot be realized in the related technology is solved, and the timeliness of fault detection and the safety of the system are improved.

Preferably, the intelligent monitoring device adjusts the rotating speed of the fan to control the temperature of the node to be monitored according to the current temperature of the node to be monitored by executing the following steps: if the current temperature of the node to be monitored is greater than a first preset value, first speed regulation information is sent to the fan, wherein the first speed regulation information is used for indicating the fan to increase the rotating speed; and if the current temperature of the node to be monitored is less than a second preset value, sending second speed regulation information to the fan, wherein the second speed regulation information is used for indicating the fan to reduce the rotating speed. The intelligent monitoring device can adjust the rotating speed of the fan by combining a system speed regulation strategy according to the current temperature of the node to be monitored, so that the effective heat dissipation of the system is ensured, and the noise and the power consumption of the fan are reduced to the maximum extent.

Preferably, the intelligent monitoring device is further used for obtaining the maximum output power of the power supply; and if the current power consumption of the node to be monitored is greater than the maximum output power of the power supply, sending a second power-off instruction to the power supply so that the power supply executes power-off operation according to the second power-off instruction. Namely, when the intelligent monitoring device monitors that the current power consumption of the node to be monitored is larger than the maximum output power of the power supply (the node to be monitored is abnormal), the power supply can be directly disconnected so as to protect the safety of the system.

The method for acquiring the maximum output power of the power supply by the intelligent monitoring device may include acquiring the maximum output power of the power supply stored in advance, or may also include requesting the maximum output power of the power supply from the power supply, which is not limited in the embodiment of the present invention.

Preferably, the intelligent monitoring device is further configured to send an alarm signal when it is determined that the current power consumption of the node to be monitored is greater than a preset maximum power consumption. The intelligent monitoring device can give an alarm according to the abnormal state of the node to be monitored, each module is controlled under the condition of ensuring safety and system reliability, and the worker is alarmed to carry out maintenance work on the premise of not influencing the system performance as far as possible.

Preferably, the monitoring agent device is further configured to read a preset voltage on the node to be monitored, and report the preset voltage to the intelligent monitoring device; the intelligent monitoring device is also used for receiving the preset voltage from the monitoring agent device; and obtaining the maximum power consumption of the node to be monitored corresponding to the preset voltage according to the mapping relation between the voltage and the power consumption of the node to be monitored. The intelligent monitoring device can detect before the system is powered on, so that problems are prevented, and the reliability of the system is further improved.

Preferably, the intelligent monitoring device is further used for obtaining the maximum output power of the power supply; if the maximum output power of the power supply is not less than the maximum power consumption of the node to be monitored, sending a power-on instruction to the monitoring agent device; and the monitoring agent device is also used for receiving the power-on instruction from the intelligent monitoring device and executing power-on operation on the node to be monitored. Namely, the intelligent monitoring device can execute the power-on operation on the system under the condition of judging no problem.

According to the invention, the technical scheme that the current temperature and the current power consumption obtained by detecting the node to be monitored in the electronic equipment by the receiving monitoring agent device are adopted, the rotating speed of the fan is adjusted according to the current temperature of the node to be monitored so as to control the temperature of the node to be monitored, and if the current power consumption of the node to be monitored is judged to be larger than the preset maximum power consumption, a first power-off instruction is sent to the monitoring agent device is adopted, so that the problem that the intelligent monitoring of a switch system cannot be realized in the related technology is solved, and the effect of intelligently monitoring the interior of the electronic equipment is further achieved.

In this embodiment, an intelligent monitoring method is provided, where the method is a method on an intelligent monitoring device side, fig. 2 is a flowchart of the intelligent monitoring method according to the embodiment of the present invention, and as shown in fig. 2, the flowchart includes the following steps:

step S202, receiving the current temperature and the current power consumption obtained by detecting the nodes to be monitored in the electronic equipment from the monitoring agent device;

step S204, adjusting the rotating speed of the fan to control the temperature of the node to be monitored according to the current temperature of the node to be monitored;

step S206, if the current power consumption of the node to be monitored is judged to be larger than the preset maximum power consumption, a first power-down instruction is sent to the monitoring agent device.

Through the steps, the intelligent monitoring device adjusts the rotating speed of the fan to control the temperature of the node to be monitored according to the current temperature and the current power consumption of the node to be monitored, which are obtained from the monitoring agent device, and sends a first power-down instruction to the monitoring agent device if the current power consumption of the node to be monitored is judged to be larger than the preset maximum power consumption, so that the problem that intelligent monitoring of a switch system cannot be realized in the related technology is solved, and the timeliness of fault detection and the safety of the system are improved.

Preferably, according to the current temperature of the node to be monitored, adjusting the rotation speed of the fan to control the temperature of the node to be monitored comprises: if the current temperature of the node to be monitored is greater than a first preset value, first speed regulation information is sent to the fan, and the first speed regulation information is used for indicating the fan to increase the rotating speed; and if the current temperature of the node to be monitored is less than a second preset value, sending second speed regulation information to the fan, wherein the second speed regulation information is used for indicating the fan to reduce the rotating speed.

In this embodiment, an intelligent monitoring method is provided, where the method is a method for monitoring a proxy device side, fig. 3 is a flowchart of the intelligent monitoring method according to an embodiment of the present invention, and as shown in fig. 3, the flowchart includes the following steps:

step S302, detecting the current temperature and the current power consumption of the node to be monitored, and reporting the current temperature and the current power consumption to an intelligent monitoring device;

step S304, receiving a first power-down instruction from the intelligent monitoring device and executing power-down operation on the node to be monitored under the condition that the intelligent monitoring device judges that the current power consumption of the node to be monitored is larger than the preset maximum power consumption.

According to the invention, the technical scheme that the current temperature and the current power consumption obtained by detecting the node to be monitored in the electronic equipment by the receiving monitoring agent device are adopted, the rotating speed of the fan is adjusted according to the current temperature of the node to be monitored so as to control the temperature of the node to be monitored, and if the current power consumption of the node to be monitored is judged to be larger than the preset maximum power consumption, a first power-off instruction is sent to the monitoring agent device is adopted, so that the problem that the intelligent monitoring of a switch system cannot be realized in the related technology is solved, and the effect of intelligently monitoring the interior of the electronic equipment is further achieved.

The embodiment of the invention aims to provide a three-dimensional monitoring system which independently operates in a switch system, is deep in three aspects of problem prevention, problem discovery and problem solution and is formed by monitoring agent units of all function boards distributed throughout the system, and the robustness of the system is guaranteed.

The following technical scheme can be adopted in the embodiment of the invention, and the intelligent monitoring system comprises:

and the intelligent monitoring unit (equivalent to the intelligent monitoring device) is used for monitoring the working state of each node of the switch system in a unified way and conditionally receiving and executing the instruction of the network control unit.

Before the system is powered on, the intelligent monitoring unit judges the in-place situation of the monitoring agent unit (equivalent to the monitoring agent device), the power module (equivalent to the power supply), the fan module (equivalent to the fan) and the corresponding link connection situation in the system. After all normal conditions, selectively releasing and powering up information for the system single board according to the maximum output power of the on-site power supply and the maximum power consumption information of the single board, which is defaulted by the single board type;

after the system is powered on, the intelligent monitoring unit collects the real-time temperature information of the single board (equivalent to the node to be monitored) reported by the monitoring agent unit and the real-time rotating speed of the fan module. In addition, the intelligent monitoring unit also collects the real-time power consumption of the single board reported by the monitoring agent unit. In the normal operation process of the system, the power supply module and the fan module of the whole system can report the working state of the system at regular time like the intelligent monitoring unit.

When the temperature of the system single board is found to exceed or be lower than the current heat dissipation capacity, the temperature of the fan is adjusted by combining a system speed regulation strategy to control the temperature of the single board, so that the effective heat dissipation of the system is ensured, and the noise and the power consumption of the fan are reduced to the maximum extent. When the intelligent monitoring unit finds that the collected single-board power consumption information is suddenly abnormal, the intelligent monitoring unit can immediately know and send a power-off command and send an alarm signal. The intelligent monitoring unit can issue instructions according to the abnormal states of the power supply module and the fan module, regulate and control each module under the condition of ensuring safety and system reliability, and alarm the working personnel to carry out maintenance work on the premise of not influencing system performance as far as possible.

And the monitoring agent unit is arranged on each node of the switch system and is provided with an intelligent monitoring agent unit which operates independently. The realization form of the agent unit is different according to different node forms, and the switch node only needs to maintain a uniform interface for the monitoring unit; the method comprises the steps of collecting and reporting the veneer type to an intelligent monitoring unit before a system function veneer is powered on, and the intelligent monitoring unit collects and judges system function node information before the system function veneer is powered on and then transfers a power-on instruction to complete system power-on.

In the running process of the system, the monitoring agent unit collects the real-time temperature and the real-time power consumption of the single board and reports the information to the intelligent monitoring unit in a timing manner.

The monitoring agent unit receives the instruction sent by the intelligent monitoring unit to carry out power-off protection on the single board.

The network communication unit is arranged to be suitable for different communication environments in order to realize cooperative monitoring in a larger range, and different communication schemes can be used along with the change of the application environment;

and the fan monitoring unit is positioned in the fan module, provides power for the fan, collects and reports the rotating speed information of the fan, receives the speed regulation information transferred by the intelligent monitoring unit and converts the speed regulation information into corresponding PWM (Pulse Width Modulation) waveform to control the fan.

As shown in fig. 4, compared with the related art, the embodiment of the present invention is implemented by a hardware circuit module, which ensures fast response processing for faults and control instructions, and has a simple and clear structure and high module cohesion. The problems are prevented before the system is powered on, the problems are found in time and are correspondingly regulated, controlled and alarmed when the system works, and stronger guarantee is provided for system operation.

In addition, the invention provides various communication interfaces, so that the invention has strong adaptability to various application environments, is compatible with the existing various communication interfaces and protects the existing investment of customers.

As shown in fig. 5, the intelligent monitoring system according to the embodiment of the present invention includes:

A. the monitoring agent unit is arranged on the network unit (namely the node to be detected) in various forms;

B. the highest node of the intelligent monitoring of the switch power supply and the intelligent monitoring unit are connected;

C. the monitoring agent unit and the intelligent monitoring unit are in independent communication link;

D. the intelligent monitoring unit is connected with an external cooperative network interface;

E. the system fan unit needs to send a link of a working state to the intelligent monitoring unit;

F. the intelligent monitoring unit reads an independent link of a system power supply.

Fig. 6 is a schematic diagram of a system power-on structure of an intelligent monitoring system monitoring agent unit according to the present invention. The monitoring agent unit CAN read preset voltages of different single boards before the single board function module is powered on and send the preset voltages to the intelligent monitoring unit through a Controller Area Network (CAN) bus, and the intelligent monitoring unit CAN analyze the maximum power consumption of the single board according to a mapping relation between the preset voltages and the power consumption of the single board.

If the system supplies power, the fan unit can meet the system power-on requirement, the intelligent monitoring unit sends a power-on instruction to the monitoring agent unit, and the monitoring agent unit immediately starts a power switch and resets the power management chip to finish the accurate control of the system power-on. The intelligent monitoring unit can sequentially control the electrification of all the single boards of the system, thereby avoiding the hidden trouble caused by the simultaneous electrification of all the single boards. The power supply of the power management chip is independent of the power supplies of other functional modules of the single board, and the power supply can ensure the power supply stability and accuracy of the power management chip. If a power supply or a fan fails in the running process of the system, the intelligent monitoring unit can send an instruction to complete the power-off process of the system;

as shown in fig. 7, a schematic diagram of a power-on control flow of an intelligent monitoring unit of the intelligent monitoring system of the present invention includes:

s702, start.

S704, judging whether all fans work normally, if not, executing a step S706; if yes, go to step S708.

And S706, stopping power-on.

And S708, collecting the maximum power consumption of each single board.

And S710, collecting the power supply capacity of the system power supply.

And S712, judging whether the power supply capacity is larger than the sum of the power consumption of each single board, if so, executing the step S714, and if not, executing the step S706.

And S714, sequentially sending a power-on instruction to the monitoring agent unit.

The system power-on process is completed by interaction of the intelligent monitoring unit and the monitoring agent unit through the CAN bus; the fan module is the key to ensure the normal heat dissipation of the system, and the completeness of the module needs to be checked before power-on.

As shown in table 1, it is a mapping table of preset voltage and maximum power consumption of a board read by a monitoring agent unit according to the embodiment of the present invention:

TABLE 1

Single board monitoring voltage	Corresponding single board power consumption
		0-1v	0-200w (according to 200w)
1-2v	200-
		2-3v	400-
3-4v	600 + 800w (according to 800w)
		4-5v	800-

As can be seen from table 1, the power supply for the preset voltage of the board is the same as the power supply of the power management chip, and is obtained by dividing the voltage on different kinds of boards; the monitoring agent unit can access the power management chip through an I2C (Inter-Integrated Circuit, two-wire serial bus) interface and read the preset voltage of the single board; the maximum power consumption is a predicted value, and the actual power consumption needs to be monitored by the monitoring agent unit in real time during the operation of the system.

In another embodiment, a software is provided, which is used to execute the technical solutions described in the above embodiments and preferred embodiments.

In another embodiment, a storage medium is provided, in which the software is stored, and the storage medium includes but is not limited to: optical disks, floppy disks, hard disks, erasable memory, etc.

It will be apparent to those skilled in the art that the modules or steps of the present invention described above may be implemented by a general purpose computing device, they may be centralized on a single computing device or distributed across a network of multiple computing devices, and alternatively, they may be implemented by program code executable by a computing device, such that they may be stored in a storage device and executed by a computing device, and in some cases, the steps shown or described may be performed in an order different than that described herein, or they may be separately fabricated into individual integrated circuit modules, or multiple ones of them may be fabricated into a single integrated circuit module. Thus, the present invention is not limited to any specific combination of hardware and software.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (9)

1. An intelligent monitoring system is applied to electronic equipment and is characterized by comprising an intelligent monitoring device and a monitoring agent device connected with the intelligent monitoring device; wherein,

the intelligent monitoring device is used for receiving the current temperature obtained by the monitoring agent device detecting the node to be monitored in the electronic equipment, and adjusting the rotating speed of the fan according to the current temperature of the node to be monitored so as to control the temperature of the node to be monitored; receiving current power consumption obtained by detecting the node to be monitored in the electronic equipment by the monitoring agent device, and sending a first power-off instruction to the monitoring agent device when judging that the current power consumption of the node to be monitored is larger than the preset maximum power consumption;

the monitoring agent device is used for detecting the current temperature and the current power consumption of the node to be monitored and reporting the current temperature and the current power consumption to the intelligent monitoring device; receiving the first power-off instruction from the intelligent monitoring device, and executing power-off operation on the node to be monitored according to the first power-off instruction;

the intelligent monitoring device is also used for receiving the preset voltage read by the monitoring agent device on the node to be monitored; obtaining the maximum power consumption of the node to be monitored corresponding to the preset voltage according to the mapping relation between the voltage and the power consumption of the node to be monitored, obtaining the maximum output power of a power supply, and sending a power-on instruction to the monitoring agent device when the maximum output power of the power supply is not less than the maximum power consumption of the node to be monitored;

the monitoring agent device is also used for reading the preset voltage of the node to be monitored and reporting the preset voltage to the intelligent monitoring device; and receiving a power-on instruction from the intelligent monitoring device, and executing power-on operation on the node to be monitored according to the power-on instruction.

2. The system of claim 1, wherein the intelligent monitoring device performs the steps of:

and adjusting the rotating speed of a fan to control the temperature of the node to be monitored according to the current temperature of the node to be monitored:

if the current temperature of the node to be monitored is greater than a first preset value, first speed regulation information is sent to the fan, and the first speed regulation information is used for indicating the fan to increase the rotating speed;

and if the current temperature of the node to be monitored is smaller than a second preset value, sending second speed regulation information to the fan, wherein the second speed regulation information is used for indicating the fan to reduce the rotating speed.

3. The system of claim 1, wherein the intelligent monitoring device is further configured to obtain a maximum output power of the power supply; and when the current power consumption of the node to be monitored is larger than the maximum output power of the power supply, sending a second power-off instruction to the power supply so that the power supply executes power-off operation according to the second power-off instruction.

4. The system according to claim 1, wherein the intelligent monitoring apparatus is further configured to send an alarm signal when determining that the current power consumption of the node to be monitored is greater than a preset maximum power consumption.

5. The system of claim 1, wherein the intelligent monitoring device is further configured to receive fault information from the fan; and sending the first power-down instruction to the monitoring agent device according to the fault information.

6. The system according to any one of claims 1 to 5, wherein the monitoring agent means is provided on the node to be monitored.

7. An intelligent monitoring method is applied to electronic equipment, and is characterized by comprising the following steps:

receiving the current temperature obtained by detecting the node to be monitored in the electronic equipment from a monitoring agent device, and adjusting the rotating speed of a fan to control the temperature of the node to be monitored according to the current temperature of the node to be monitored; and the number of the first and second groups,

receiving current power consumption obtained by detecting a node to be monitored in the electronic equipment from a monitoring agent device, and if the current power consumption of the node to be monitored is judged to be larger than the preset maximum power consumption, sending a first power-off instruction to the monitoring agent device;

receiving preset voltage of the node to be monitored read by the monitoring agent device, obtaining maximum power consumption of the node to be monitored corresponding to the preset voltage according to the mapping relation between the voltage and the power consumption of the node to be monitored, obtaining the maximum output power of a power supply, and sending a power-on instruction to the monitoring agent device when the maximum output power of the power supply is not less than the maximum power consumption of the node to be monitored so as to execute power-on operation on the node to be monitored.

8. The intelligent monitoring method of claim 7, wherein adjusting the rotational speed of the fan to control the temperature of the node to be monitored based on the current temperature of the node to be monitored comprises:

if the current temperature of the node to be monitored is greater than a first preset value, first speed regulation information is sent to the fan, and the first speed regulation information is used for indicating the fan to increase the rotating speed;

and if the current temperature of the node to be monitored is smaller than a second preset value, sending second speed regulation information to the fan, wherein the second speed regulation information is used for indicating the fan to reduce the rotating speed.

9. An intelligent monitoring method is applied to electronic equipment, and is characterized by comprising the following steps:

detecting the current temperature and the current power consumption of a node to be monitored, and reporting the current temperature and the current power consumption to an intelligent monitoring device;

under the condition that the intelligent monitoring device judges that the current power consumption of the node to be monitored is larger than the preset maximum power consumption, receiving a first power-down instruction from the intelligent monitoring device, and executing power-down operation on the node to be monitored according to the first power-down instruction;

further comprising:

reading a preset voltage of a node to be monitored, reporting the preset voltage to an intelligent monitoring device, so that the intelligent monitoring device obtains the maximum power consumption of the node to be monitored corresponding to the preset voltage according to the mapping relation between the voltage and the power consumption of the node to be monitored, obtains the maximum output power of a power supply, and sends a power-on instruction to a monitoring agent device when the maximum output power of the power supply is not less than the maximum power consumption of the node to be monitored;

and receiving a power-on instruction from the intelligent monitoring device, and executing power-on operation on the node to be monitored according to the power-on instruction.

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