CN116912030B - Power market abnormal operation condition monitoring method and device based on block chain - Google Patents

Abstract

When the monitoring platform transmits B1 to the field platform to acquire feedback information, if the first feedback information is not received in delta U1, UFTU1 is transmitted to the field platform, and if the first interception feedback information is not received in delta U2, the monitoring platform is set to be in a second state, at the moment, the monitoring platform can acquire the first feedback information through the field platform by the intermediate platform, the identification code of the monitoring platform is not required to be changed by changing the monitoring platform, the time consumption is reduced, and the efficiency of the monitoring platform to acquire dynamic adjustable information through the field platform can be improved.

Description

Power market abnormal operation condition monitoring method and device based on block chain

Technical Field

The invention belongs to the technical field of power markets, and particularly relates to a block chain-based power market abnormal operation condition monitoring method and device.

Background

In the prior art scheme, the patent number is 202210630610.4 and the patent name is 'a real-time power demand response method and related equipment based on a blockchain', a monitoring platform obtains each real-time demand response sub-instruction through a field platform and according to dynamic adjustable information, and performs blockchain uplink on each real-time demand response sub-instruction to finally form a corresponding transaction settlement record.

The structure for the monitoring platform to acquire the dynamic adjustable information through the on-site platform comprises: the monitoring platform is arranged in the distributed energy storage power station and stores dynamic adjustable information, the monitoring platform is arranged in a remote area outside the distributed energy storage power station, in detail, the monitoring platform can inquire the field platform to obtain the dynamic adjustable information, the field platform confirms the field platform through the current website of the monitoring platform, and the corresponding dynamic adjustable information is transmitted to the field platform to obtain the dynamic adjustable information.

However, because the privacy requirement of the site platform is not low, when the site platform performs recognition on the website of the monitoring platform, the site platform can generate misjudgment, namely the site platform recognizes the current website of the monitoring platform as an abnormal website, so that the monitoring platform is set to refuse to read the site platform, at the moment, the monitoring platform cannot acquire dynamic adjustable information in the site platform, and the site platform needs to be manually started to update the website of the site platform, so that the site platform cannot acquire the dynamic adjustable information with high efficiency when the consumption is not small.

Disclosure of Invention

In order to solve the defects in the prior art, the invention provides a block chain-based power market abnormal operation condition monitoring method and device, when a monitoring platform transmits B1 to a field platform to acquire feedback information, if the feedback information I is not received in delta U1, UFTU1 is transmitted to the field platform, and if the interception feedback information I is not received in delta U2, the monitoring platform is set to be in a second condition, at this time, the monitoring platform can acquire the feedback information I through the field platform by virtue of an intermediate platform, the identification code of the monitoring platform does not need to be changed by changing the monitoring platform, the time consumption is reduced, and the high efficiency of the monitoring platform for acquiring dynamic adjustable information through the field platform can be improved.

The invention adopts the following technical scheme.

A blockchain-based power market abnormal operation condition monitoring method, comprising:

The monitoring platform obtains all real-time demand response sub-instructions through the on-site platform and according to the dynamic adjustable information, and performs block chain uplink on all the real-time demand response sub-instructions to finally form corresponding transaction settlement records;

a method for a monitoring platform to obtain dynamically tunable information via a field platform, comprising:

The monitoring platform located at the first condition is used for executing a first setting stage, wherein the first setting stage comprises:

step 1-1: when the monitoring platform needs to take dynamic adjustable information, forming an information acquisition poll to obtain B1= { B, c, ebub };

Here, B is the identifier of the monitoring platform, c is the identifier of the field platform, ebub is the poll message one, and B1 is used to request the field platform to return feedback information one to the monitoring platform, and the feedback information one is associated with ebub 1.

Step 1-2: delivering B1 to a site platform;

Step 1-3: if feedback information I is not received in the period one delta U1, transmitting interception polling to the field platform to obtain a UFTU = { b, c }; here, UFTU is configured to require the field platform to transmit back the first listening feedback information to the monitoring platform;

step 1-4: if the interception feedback information I is not received in the period II delta U2, setting the monitoring platform to be in a second state; Δu2 < Δu1.

Preferably, the moment when the monitoring platform located in the first condition transmits the B1 to the field platform is taken as the first judgment moment; after the monitoring platform positioned in the first condition transmits B1 to the field platform, whether feedback information I is received in the delta U1 taking the first judgment moment as the starting moment or not can be judged; if the monitoring platform in the first condition receives the feedback information I in the delta U1, the monitoring platform is identified by the field platform as a device which permits the field platform to be read, namely the monitoring platform correctly receives the feedback information I transmitted by the field platform according to the B1; if the monitoring platform at condition one does not receive feedback information one in ΔU1, then the monitoring platform forms UFTU and communicates UFTU1 to the field platform.

Preferably, the moment when the monitoring platform located in the first condition transmits UFTU a to the field platform is taken as a determination moment II; after the monitoring platform located in the first condition transmits UFTU a to the field platform, whether interception feedback information I is received in the delta U2 taking the second judgment time as the starting time or not can be judged;

If the first interception feedback information is received in the delta U2, the monitoring platform is a device which is recognized by the field platform as a device which can be read by the field platform;

If the first interception feedback information is not received in the delta U2, the monitoring platform is identified by the field platform as a device for refusing to read the field platform, and the monitoring platform can be changed to a second condition.

Preferably, the monitoring platform located in the second condition is configured to execute a second setting stage, where the second setting stage includes:

Step 2-1: forming an information acquisition query two B2= { B, d, ebub1}, according to the information acquisition query one B1; here, d is the authentication code of the intermediate platform;

Step 2-2: transferring B2 towards the intermediate platform;

step 2-3: and receiving feedback information I returned by the middle platform.

Preferably, ebub1 can be obtained in B1 after the monitoring platform changes to condition two, and B2 is formed according to the identifier of the monitoring platform corresponding to B2, the identifier of the field platform corresponding to B2 and ebub, that is, b2= { B, d, ebub1}.

Preferably, the intermediate platform is a device which is recognized by the field platform as a device for permitting reading, after the monitoring platform in the second condition transmits the B2 to the intermediate platform, the intermediate platform can recognize the first feedback information corresponding to ebub in the B2 and transmit the first feedback information back to the monitoring platform in the second condition, and at this time, the monitoring platform in the second condition can receive the first feedback information.

Preferably, the intermediate platform is configured to perform a third setting stage, where the third setting stage includes:

Step 3-1: forming an information acquisition poll three B3= { d, c, ebub1}, according to the information acquisition poll two B2;

step 3-2: delivering B3 towards the site platform;

step 3-3: collecting feedback information I returned by the field platform;

Step 3-4: and returning feedback information to the monitoring platform.

Preferably, stage two further comprises:

executing the moment of setting the monitoring platform to be in a second condition as a change moment U1;

Obtaining a change time biu2=u1+Δu3; here, Δu3 is a period three set in advance;

From U2, periodically transmitting UFTU a to the field platform; the corresponding timing period of the timed transfer UFTU to the field platform is Δu3;

After each pass UFTU1, if one snoop feedback is received in ΔU2, the monitoring platform is set to condition one.

Preferably, when the number of monitoring platforms is several, Δu3 is determined as follows:

obtaining the bandwidth Xje of the intermediate platform and the number Ovn of the monitoring platforms;

taking a listening period group OJNF = { u1, u2, u3...uo }; here, uj is the j-th listening period, j=1, 2, 3..o, L is a preset factor, χ is a correction factor I, δ is a correction factor II, uj+1=η is uj, η is a ratio factor, 0 < L1 +.ltoreq.l2 < 1, L1 is a constant I, L2 is a constant II;

O listening treatments are sequentially executed, and an error frequency group n= { N1, N2, n3...no }; here, nj is the error frequency of the intermediate platform during the execution of the jth snoop treatment, which is to control the monitoring platform to execute the running condition two with uj as Δu3 and hold period four;

The lowest frequency N _njo =njo (N), where njo (N) is a preset equation for obtaining the lowest amount of N;

If n _njo corresponds to a listening period, regarding the listening period corresponding to n _njo as DeltaU 3;

If n _njo corresponds to a number of listening periods, the lowest listening period of the number of listening periods corresponding to n _njo is taken as Δu3.

Preferably, both B1 and UFTU1 are formed and transmitted according to the first communication standard, and the first phase executed by the monitoring platform at the first status further includes:

If feedback information I is not received in the period one delta U1, a interception poll is formed according to UFTU1 and a communication standard II to obtain two UFTU 2= { b, c }; the second communication standard is different from the first communication standard; UFTU2 is used for requesting the field platform to transmit the interception feedback information II back to the monitoring platform;

Delivering UFTU to the site platform;

the corresponding steps 1-4 comprise:

After UFTU and UFTU are transmitted, if the first interception feedback information and the second interception feedback information are not received in the second delta U2 period, setting the monitoring platform to be in a second state;

the second stage executed by the corresponding monitoring platform located in the second condition further comprises:

from U2, periodically transmitting UFTU to the field platform; the corresponding timing period of the timed transfer UFTU to the field platform is Δu3;

After each of the above passes UFTU1, if the first snoop feedback is received in Δu2, the monitoring platform is set to condition one, including:

After each transfer UFTU and UFTU2, if either the first or second snoop feedback information is received in ΔU2, the monitoring platform is set to condition one.

Preferably, UFTU1 corresponds to the highest feedback period Δu4, Δu4 < Δu2; UFTU2 corresponding to the highest feedback period DeltaU 5, deltaU 2 < DeltaU 5 is less than or equal to DeltaU 2+ DeltaU 3; here, Δu4 is the highest period size from the time of delivering UFTU a to the time of receiving the corresponding listening feedback information one; Δu5 is the highest time period from the time of transmitting UFTU to the time of receiving the corresponding interception feedback information two; the corresponding stage two also comprises:

after setting the monitoring platform to the second condition, the monitoring platform is set to the first condition if the interception feedback information is received in the delta U3 after setting the monitoring platform to the second condition.

Preferably, the identifier is set to a website, and the field platform is further configured to perform the following method:

Collecting B1;

Judging whether B in B1 belongs to a preset website group or not;

if the web address group is not included, feedback information I is returned to the monitoring platform;

the on-site platform is provided with an isolation list, the isolation list is used for storing identification codes refusing to read the on-site platform, and the on-site platform is also used for executing the following method:

if the website is classified into the website group, adding b to the isolation list;

the corresponding stage two is also used for executing the following method:

When the monitoring platform needs to take dynamic adjustable information, forming information acquisition polling to obtain four B4= { B, d, ebub }; here ebub is poll message two;

transferring B4 towards the intermediate platform;

Receiving feedback information II returned by the middle platform; feedback information II corresponds to ebub;

the intermediate platform is also used for executing the following method:

forming an information acquisition query five B5= { d, c, ebub2} according to the information acquisition query four B4;

Delivering B5 towards the site platform;

Collecting feedback information II returned by the field platform;

And returning the feedback information to the monitoring platform.

A blockchain-based power market abnormal operating condition monitoring device, comprising:

The monitoring platform, the field platform and the intermediate platform are all in communication connection with the monitoring platform, and the field platform is in communication connection with the intermediate platform; the monitoring platform is provided with a first condition and a second condition, the field platform is arranged in the distributed energy storage power station and stores dynamic adjustable information, and the monitoring platform is arranged in a remote area outside the distributed energy storage power station;

The monitoring platform positioned in the first condition is used for executing the first setting stage; the monitoring platform positioned in the second condition is used for executing the second setting stage; the intermediate platform is used for executing the setting stage three.

Compared with the prior art, the method has the advantages that when the monitoring platform transmits B1 to the field platform to acquire feedback information, if the first feedback information is not received in the delta U1, UFTU is transmitted to the field platform, and if the first interception feedback information is not received in the delta U2, the monitoring platform is set to be in a second state, at this time, the monitoring platform can acquire the first feedback information through the field platform by the intermediate platform, the identification code of the monitoring platform does not need to be changed by changing the monitoring platform, the time consumption is reduced, and the high efficiency of the monitoring platform for acquiring dynamic adjustable information through the field platform can be improved.

Drawings

FIG. 1 is a partial flow chart of a stage one of the present invention;

FIG. 2 is a partial flow chart of stage two of the present invention;

FIG. 3 is a partial flow chart of stage three of the present invention;

FIG. 4 is a block chain based power market abnormal operating condition monitoring device partially block chain based power market partially block diagram according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be clearly and completely expressed with reference to the drawings in the embodiments of the present application. The embodiments of the application that are presented are only some of the embodiments of the application and not all of the embodiments. Based on the spirit of the present application, one of ordinary skill in the art would obtain additional embodiments without inventive faculty, all falling within the scope of the application.

As shown in fig. 1, the method for monitoring abnormal operation state of an electric power market based on a blockchain includes:

the monitoring platform obtains all real-time demand response sub-instructions through the on-site platform and according to the dynamic adjustable information, and performs block chain uplink on all the real-time demand response sub-instructions to finally form corresponding transaction settlement records; the dynamic adjustable information is the dynamic adjustable information of the block chain uplink of each distributed energy storage power station; obtaining each real-time demand response sub-instruction, decomposing the real-time demand response instruction according to the dynamic adjustable information, and obtaining each real-time demand response sub-instruction; finally, corresponding transaction settlement records are formed and are obtained through each distributed energy storage power station, and demand response operation is executed according to corresponding real-time demand response sub-instructions; and after the corresponding distributed energy storage power station is determined to achieve the demand response operation, finally forming a corresponding transaction settlement record.

The electric power market abnormal operation condition monitoring device based on the block chain comprises a monitoring platform, a field platform and an intermediate platform, wherein the field platform and the intermediate platform are both in communication connection with the monitoring platform, and the field platform is in communication connection with the intermediate platform; the monitoring platform has a first condition and a second condition, and the initial condition of the monitoring platform is the first condition.

A method for a monitoring platform to obtain dynamically tunable information via a field platform, comprising:

The monitoring platform located at the first condition is used for executing a first setting stage, wherein the first setting stage comprises:

step 1-1: when the monitoring platform needs to take dynamic adjustable information, forming an information acquisition poll to obtain B1= { B, c, ebub };

here, B is the identifier of the monitoring platform, c is the identifier of the field platform, ebub is the poll message one, and B1 is used to request the field platform to return feedback information one to the monitoring platform, and the feedback information one is associated with ebub 1. The identification code of the monitoring platform is the unique identification number set for the monitoring platform, and the identification code of the field platform is the unique identification number set for the field platform. The polling message can contain dynamic adjustable information which is required to be formed on the field platform in which time period, and the feedback information is the dynamic adjustable information formed on the field platform in which time period.

Step 1-2: delivering B1 to a site platform;

here, after the monitoring platform located in condition one forms B1, B1 can be transferred to the site platform based on the authentication code c of the site platform within A1.

Step 1-3: if feedback information I is not received in the period one delta U1, transmitting interception polling to the field platform to obtain a UFTU = { b, c }; here, UFTU is configured to require the field platform to transmit back the first listening feedback information to the monitoring platform; the size of the period one is set in advance.

In a preferred but non-limiting embodiment of the present invention, the moment when the monitoring platform located in the first condition transmits B1 to the on-site platform can be used as the determination moment one; after the monitoring platform positioned in the first condition transmits B1 to the field platform, whether feedback information I is received in the delta U1 taking the first judgment moment as the starting moment or not can be judged; if the monitoring platform in the first condition receives the feedback information I in the delta U1, the monitoring platform is identified by the field platform as a device which permits the field platform to be read, namely the monitoring platform correctly receives the feedback information I transmitted by the field platform according to the B1; if the monitoring platform at condition one does not receive feedback information one in ΔU1, then the monitoring platform forms UFTU and communicates UFTU1 to the field platform.

Step 1-4: if the interception feedback information I is not received in the period II delta U2, setting the monitoring platform to be in a second state; Δu2 < Δu1; the size of the period two is set in advance.

In a preferred but non-limiting embodiment of the present invention, the moment at which the monitoring platform located in the first condition transmits UFTU to the site platform can be used as decision moment two; after the monitoring platform located in the first condition transmits UFTU a to the field platform, whether interception feedback information I is received in the delta U2 taking the second judgment time as the starting time or not can be judged;

If the first interception feedback information is received in the delta U2, the fact that the monitoring platform is a device which is recognized by the field platform as a device which can be read by the field platform is represented, and the first interception feedback information is not received in the delta U1 because the monitoring platform is formed by the delay of a 4G network or the other reasons, and the first interception feedback information can be obtained by executing an interface updating action on a corresponding interface of the monitoring platform without changing the operation condition of the monitoring platform;

If the first interception feedback information is not received in the delta U2, the monitoring platform is identified by the field platform as a device for refusing to read the field platform, and the monitoring platform can be changed to a second condition.

In a preferred but non-limiting embodiment of the present invention, as shown in fig. 2, the monitoring platform located in the second condition is used to execute the second setting stage, where the second setting stage includes:

Step 2-1: forming an information acquisition query two B2= { B, d, ebub1}, according to the information acquisition query one B1; here, d is the authentication code of the intermediate platform; the authentication code of the intermediate platform is a unique identification number set for the intermediate platform.

In a preferred but non-limiting embodiment of the present invention, ebub1 can be obtained from B1 after the monitor platform changes to condition two, and B2 is formed according to the identifier of the monitor platform corresponding to B2, the identifier of the field platform corresponding to B2 and ebub, that is, b2= { B, d, ebub1}.

Step 2-2: transferring B2 towards the intermediate platform;

here, after the monitoring platform located in the second condition forms B2, B2 can be transferred to the intermediate platform based on the identifier d of the site platform in B2.

Step 2-3: and receiving feedback information I returned by the middle platform.

In a preferred but non-limiting embodiment of the present invention, the intermediate platform is a device that is recognized by the on-site platform as a device that permits reading, and after the monitoring platform located in the second condition transmits B2 to the intermediate platform, the intermediate platform can recognize the feedback information one corresponding to ebub in B2 and transmit the feedback information one back to the monitoring platform located in the second condition, at this time, the monitoring platform located in the second condition can receive the feedback information one.

In a preferred but non-limiting embodiment of the present invention, as shown in fig. 3, the intermediate platform is configured to perform a third setup phase, where the third setup phase includes:

Step 3-1: forming an information acquisition poll three B3= { d, c, ebub1}, according to the information acquisition poll two B2;

Here, after the intermediate platform receives B2 transmitted by the monitoring platform located in the second condition, ebub1 in B2 can be obtained, and B3 is formed according to the identifier of the monitoring platform corresponding to B3, the identifier of the field platform corresponding to B3 and ebub, that is, b3= { d, c, ebub1}.

Step 3-2: delivering B3 towards the site platform;

here, after the intermediate platform forms B3, B3 can be transferred to the site platform based on the authentication code c of the site platform within B3.

Step 3-3: collecting feedback information I returned by the field platform;

Here, after the intermediate platform transmits A3 to the field platform, the field platform can identify the feedback information one corresponding to ebub a in B3 and transmit the feedback information one back to the intermediate platform, and at this time, the intermediate platform can obtain the feedback information one.

Step 3-4: and returning feedback information to the monitoring platform.

Here, after the intermediate platform obtains the feedback information one, the feedback information one can be returned to the monitoring platform according to the identification code B of the monitoring platform in B2.

Therefore, when the monitoring platform transmits B1 to the field platform to obtain feedback information, if the feedback information one is not received in Δu1, then UFTU is transmitted to the field platform, and if the interception feedback information one is not received in Δu2, the monitoring platform is set to be in a second state, at this time, the monitoring platform can obtain the feedback information one through the field platform via the intermediate platform, the monitoring platform does not need to be changed to change the identification code of the monitoring platform, the time consumption is reduced, and the efficiency of the monitoring platform to obtain the dynamic adjustable information through the field platform can be improved.

In addition, when the corresponding feedback information of B1 is not received in the delta U1, UFTU1 with small information quantity is transmitted to the field platform to more efficiently verify whether the field platform is a device for identifying the monitoring platform as refusing to read, so that the first feedback information of B1 is not received by the monitoring platform, and the first feedback information of B1 is received by the field platform, which is a device for identifying the monitoring platform as permitting to read the field platform, thereby reducing excessive application of the intermediate platform and reducing the operation load of the intermediate platform.

In a preferred but non-limiting embodiment of the present invention, stage two further comprises:

executing the moment of setting the monitoring platform to be in a second condition as a change moment U1;

Obtaining a change time biu2=u1+Δu3; here, Δu3 is a period three set in advance;

From U2, periodically transmitting UFTU a to the field platform; the corresponding timing period of the timed transfer UFTU to the field platform is Δu3;

After each pass UFTU1, if one snoop feedback is received in ΔU2, the monitoring platform is set to condition one.

In this way, after the monitoring platform changes into the second condition through the first condition, after passing through the Δu3, the monitoring platform located in the second condition can transmit UFTU1 to the field platform at regular time, and after transmitting UFTU1 to the field platform each time, whether interception feedback information one is received in the Δu2 can be determined; if the first interception feedback information is received, the monitoring platform is identified by the field platform as a device which permits reading the field platform, the monitoring platform can be set to be in a first state, and the above timed transmission UFTU to the field platform is stopped; if the first interception feedback information is not received, the monitoring platform is identified by the field platform as a device for refusing to read the field platform, and the TEST1 can be transmitted to the field platform when the later timing period arrives.

Therefore, after the monitoring platform changes to the second condition through the first condition, the monitoring platform positioned in the second condition can regularly verify whether the on-site platform can be read, so that the probability that the monitoring platform changes to the second condition due to misdetermination and continuously operates in the second condition is reduced, the occupation amount of the intermediate platform is reduced, and the operation load of the intermediate platform can be further reduced.

In a preferred but non-limiting embodiment of the invention, when the number of monitoring platforms is several, Δu3 can be identified by:

obtaining the bandwidth Xje of the intermediate platform and the number Ovn of the monitoring platforms;

taking a listening period group OJNF = { u1, u2, u3...uo }; here, uj is the j-th listening period, j=1, 2, 3..o, L is a preset factor, χ is a correction factor I, δ is a correction factor II, uj+1=η is uj, η is a ratio factor, 0 < L1 +.ltoreq.l2 < 1, L1 is a constant I, L2 is a constant II;

O listening treatments are sequentially executed, and an error frequency group n= { N1, N2, n3...no }; here, nj is the error frequency of the intermediate platform during the execution of the jth snoop treatment, which is to control the monitoring platform to execute the running condition two with uj as Δu3 and hold period four;

The lowest frequency N _njo =njo (N), where njo (N) is a preset equation for obtaining the lowest amount of N;

If n _njo corresponds to a listening period, regarding the listening period corresponding to n _njo as DeltaU 3;

If n _njo corresponds to a number of listening periods, the lowest listening period of the number of listening periods corresponding to n _njo is taken as Δu3.

Here, each error frequency is a frequency at which the intermediate platform operates abnormally because a large amount of information is handled concurrently during execution of the corresponding snoop treatment, and as if the frequency at which the intermediate platform crashes and the frequency at which the blocking occurs during a certain snoop treatment are ten, the error frequency of the snoop treatment is ten.

Here, can be based onRegarding uj+1=η, identifying a listening period group OJNF, then performing a round of listening treatment according to each listening period, obtaining an error frequency group N through o times of listening treatment, identifying N _njo which is the lowest error frequency in N, regarding a corresponding listening period as Δu3 if N _njo corresponds to a listening period in N, and regarding a lowest listening period in a plurality of listening periods corresponding to N _njo as Δu3 if N _njo corresponds to a plurality of listening periods.

As if Xje =10 ⁷bps,Ovn＝3*10⁸, from which U1 can be considered three minutes, Δu3 can be considered as last through several listening treatmentsMinute, ΔU3 is/>During operation of the minute blockchain-based power market abnormal operation condition monitoring device, the phenomenon that an intermediate platform runs abnormally due to concurrent handling of a large amount of information is extremely low.

Therefore, Δu3 of the blockchain-based power market abnormal operation condition monitoring device can be identified by a more proper amount through several interception treatments, so that the phenomenon that an intermediate platform works abnormally due to concurrent treatment of a large amount of information is reduced.

Here can be: l1 is more than or equal to 0.38 and less than or equal to 0.76,0.76, l2 is more than or equal to 0.92;

and 0.38.ltoreq.η.ltoreq.0.92, optimally, η=0.76.

Therefore, when random round of interception treatment is executed, since Δu3 corresponding to current round of interception treatment is an amount obtained by multiplying Δu3 corresponding to previous round of interception treatment by η, setting η to 0.76 can make the interval between Δu3 corresponding to current round of interception treatment and Δu3 corresponding to previous round of interception treatment more appropriate, the probability of executing interception treatment different times according to very similar Δu3 can be reduced, so that the probability of executing useless interception treatment can be reduced, and the efficiency of recognizing invalidity can be improved; synchronous increment of interception treatment frequency is accompanied, the interval quantity of corresponding delta U3 of interception treatment at present and corresponding delta U3 of interception treatment at the previous round can be slowly reduced, namely, interception treatment of a plurality of rounds can be executed under the condition of optimizing an operation intermediate platform, so that when the electric power market abnormal operation condition monitoring device based on blockchain executes operation by utilizing the last confirmed delta U3, the operation intermediate platform can be more optimized under the condition that the intermediate platform is abnormally less.

In a preferred but non-limiting embodiment of the present invention, both B1 and UFTU1 are formed and transmitted according to a first communication standard, according to which stage one of the monitoring platform execution at condition one further comprises:

If feedback information I is not received in the period one delta U1, a interception poll is formed according to UFTU1 and a communication standard II to obtain two UFTU 2= { b, c }; the second communication standard is different from the first communication standard; UFTU2 is used for requesting the field platform to transmit the interception feedback information II back to the monitoring platform;

Delivering UFTU to the site platform;

According to this, the corresponding steps 1-4 comprise:

After UFTU and UFTU are transmitted, if the first interception feedback information and the second interception feedback information are not received in the second delta U2 period, setting the monitoring platform to be in a second state;

the second stage executed by the corresponding monitoring platform located in the second condition further comprises:

from U2, periodically transmitting UFTU to the field platform; the corresponding timing period of the timed transfer UFTU to the field platform is Δu3;

After each of the above passes UFTU1, if the first snoop feedback is received in Δu2, the monitoring platform is set to condition one, including:

After each transfer UFTU and UFTU2, if either the first or second snoop feedback information is received in ΔU2, the monitoring platform is set to condition one.

Here, B1, B2 and UFTU are all formed and transmitted according to a first communication standard, UFTU2 is formed and transmitted according to a second communication standard, the first communication standard is different from the second communication standard, the first communication standard can use the FTP standard, the second communication standard can use the NFS standard, according to which if the monitoring platform in the first condition does not receive the feedback information in Δu1, UFTU2 is transmitted to the on-site platform when transmitting UFTU1 to the on-site platform, the moment when the monitoring platform in the first condition transmits UFTU1 and UFTU2 to the on-site platform can be taken as a determination moment two, and then whether the monitoring feedback information in Δu2 starting from the determination moment two is received or not can be determined as the interception feedback information one and the interception feedback information two; if the first interception feedback information or the second interception feedback information is received in the delta U2, the monitoring platform is identified by the field platform to be a state structure which permits reading of the field platform, and the first interception feedback information can be obtained by executing page updating operation on the monitoring platform without changing the operation state of the monitoring platform; if the first interception feedback information is not received in the delta U2 and the second interception feedback information is not received in the delta U2, the monitoring platform is identified by the field platform as equipment for refusing to read the field platform, and then the monitoring platform can be changed to the second condition.

Similarly, from the monitoring platform in the second condition via U2, the timing platform transmits UFTU to the site platform at timing when the timing platform transmits UFTU to the site platform, and the timing period corresponding to the timing platform transmitting UFTU to the site platform is the same as the timing period corresponding to the timing platform transmitting UFTU to the site platform; after each transfer UFTU and UFTU to the field platform, it can be determined whether or not snoop feedback information one and snoop feedback information two were received in Δu2, which uses the time of the transfer UFTU and UFTU2 as the starting time; if the first interception feedback information or the second interception feedback information is received in the delta U2, the monitoring platform is identified by the field platform as a device which permits reading of the field platform, the monitoring platform can be set to be in a first state, and the above timed transmission UFTU to the field platform and the timed transmission UFTU to the field platform are stopped; if the Δu2 can only not receive the first and second interception feedback information, it represents that the monitoring platform is recognized by the field platform as a device that refuses to read the field platform, and can then transmit UFTU and UFTU to the field platform when a certain time period arrives.

Therefore, UFTU is formed and transmitted according to the first communication standard, UFTU is formed and transmitted according to the second communication standard, and when the monitoring platform is verified whether the device is recognized as a device refusing to read the field platform by the field platform, UFTU1 and UFTU corresponding to different communication standards are synchronously transmitted, and verification values can be obtained only by collecting corresponding interception feedback information randomly in UFTU and UFTU2, so that the efficiency of the monitoring platform in executing operation condition change can be improved.

In a preferred but non-limiting embodiment of the present invention, UFTU1 corresponds to the highest feedback period Δu4, Δu4 < Δu2; UFTU2 corresponding to the highest feedback period DeltaU 5, deltaU 2 < DeltaU 5 is less than or equal to DeltaU 2+ DeltaU 3; here, Δu4 is the highest period size from the time of delivering UFTU a to the time of receiving the corresponding listening feedback information one; Δu5 is the highest time period from the time of transmitting UFTU to the time of receiving the corresponding interception feedback information two; according to this, the corresponding phase two further comprises:

after setting the monitoring platform to the second condition, the monitoring platform is set to the first condition if the interception feedback information is received in the delta U3 after setting the monitoring platform to the second condition.

Here, under the condition that the monitoring platform is identified by the field platform as a device for permitting reading of the field platform, the monitoring platform transmits UFTU a period from receiving the corresponding first interception feedback information, and the period from receiving UFTU a corresponding second interception feedback information is also performed according to the operation conditions of the monitoring platform and the field platform, and the period from receiving UFTU a corresponding second interception feedback information is also performed according to the period from receiving the corresponding first interception feedback information, and the period from receiving the corresponding second interception feedback information is also performed according to the period from receiving the corresponding second interception feedback information:

If the monitoring platform in the first condition fails to receive the first interception feedback information because the TEST1 transmits the loss in the period two Δu2, and fails to receive the second interception feedback information because UFTU1 is overdue, the operation condition of the monitoring platform changes to the second condition, whether the second interception feedback information corresponding to UFTU is received in the Δu3 can be determined, if the second interception feedback information is received, the monitoring platform is identified as a device for permitting the on-site platform to be read, and the operation condition of the monitoring platform can be changed to the first condition at this time, so that the monitoring platform can change to the first condition more efficiently, the occupation amount of the intermediate platform can be reduced, and the operation load of the intermediate platform can be further reduced.

In a preferred but non-limiting embodiment of the invention, the identifier is set to a web address, according to which the on-site platform is further adapted to perform the following method:

Collecting B1;

Judging whether B in B1 belongs to a preset website group or not;

if the web address group is not included, feedback information I is returned to the monitoring platform;

Here, the identifier can be set to a website, and the corresponding b is the website of the monitoring platform, c is the website of the site platform, and d is the website of the intermediate platform. The site platform can collect B1= { B, c, ebub1}, and judge whether B in B1 belongs to a preset website group or not, if not, the site platform can identify feedback information I according to ebub1 in B1 and return the feedback information I to the monitoring platform; here, b is not assigned to a set of web sites set in advance, so that b is recognized by the site platform as a web site meeting the preset specification.

The on-site platform is provided with an isolation list, the isolation list is used for storing identification codes refusing to read the on-site platform, and according to the identification codes, the on-site platform is further used for executing the following method:

if the website is classified into the website group, adding b to the isolation list;

here, if b is assigned to the web site group, then b is identified by the site platform as a web site meeting the preset specification, and b is added to the isolation list. Just like if b is identified by the site platform as an external website or a website with low popularity, etc., b is added to the isolation list.

The corresponding stage two is also used for executing the following method:

When the monitoring platform needs to take dynamic adjustable information, forming information acquisition polling to obtain four B4= { B, d, ebub }; here ebub is poll message two;

transferring B4 towards the intermediate platform;

Receiving feedback information II returned by the middle platform; feedback information II corresponds to ebub;

when the monitoring platform needs to take the dynamic adjustable information, B4 can be formed in the monitoring platform, the identification code of the monitoring platform corresponding to B4, the identification code of the field platform corresponding to B4 and the query message II are arranged in the monitoring platform, namely B4= { B, d, ebub }, ebub2 is used for requesting the field platform to identify the feedback information II corresponding to B4, then the B4 is transmitted to the intermediate platform according to the identification code d of the field platform in B4, and finally the feedback information II identified in the field platform and returned by the intermediate platform can be collected.

The intermediate platform is also used for executing the following method:

forming an information acquisition query five B5= { d, c, ebub2} according to the information acquisition query four B4;

Delivering B5 towards the site platform;

Collecting feedback information II returned by the field platform;

And returning the feedback information to the monitoring platform.

Here, after the intermediate platform receives B4 transmitted by the monitoring platform located in the second condition, ebub in B4 can be obtained, and B5 is formed according to the identifier of the monitoring platform corresponding to B5, the identifier of the field platform corresponding to B5 and ebub, that is, b5= { d, c, ebub }, then B5 can be transmitted to the field platform according to the identifier c of the field platform in B5, the field platform can identify ebub corresponding to feedback information two in B5, and the feedback information two is transmitted back to the intermediate platform, and the intermediate platform can transmit feedback information two to the monitoring platform according to the identifier B of the monitoring platform in B4.

As shown in fig. 4, the device for monitoring abnormal operation conditions of an electric power market based on a blockchain according to the present invention includes:

The monitoring platform, the field platform and the intermediate platform are all in communication connection with the monitoring platform, and the field platform is in communication connection with the intermediate platform; the monitoring platform is provided with a first condition and a second condition, the field platform is arranged in the distributed energy storage power station and stores dynamic adjustable information, and the monitoring platform is arranged in a remote area outside the distributed energy storage power station; the monitoring platform, the intermediate platform and the field platform are all computers and are located in the 4G network.

The monitoring platform positioned in the first condition is used for executing the first setting stage; the monitoring platform positioned in the second condition is used for executing the second setting stage; the intermediate platform is used for executing the setting stage three.

The present disclosure can be a system, method, and/or computer program product. The computer program product can include a computer-readable storage medium having computer-readable program instructions embodied thereon for causing a processor to perform each aspect of the present disclosure.

The computer readable auxiliary medium can be a tangible power grid line capable of holding and auxiliary instructions for execution of the power grid line operations by the instructions. The computer readable accessory medium can be, but is not limited to, an electric accessory grid line, a magnetic accessory grid line, an optical accessory grid line, an electromagnetic accessory grid line, a semiconductor accessory grid line, or any suitable combination of the foregoing. Still further examples (non-enumerated list) of the computer-readable storage medium include: portable computer disk, hard disk, random Access Memory (RAM), read-only memory (RyM), erasable programmable read-only memory (EPRyM or flash memory), static Random Access Memory (SRAM), portable compact disk read-only memory (HD-RyM), digital versatile disk (DXD), memory stick, floppy disk, mechanical code grid line, punch card like with instructions attached thereto or bump structure in a groove, optionally properly merging with the above. Computer-readable storage media as used herein are not to be construed as transient messages themselves, such as radio waves or otherwise freely propagating electromagnetic waves, electromagnetic waves propagating through a waveguide or otherwise transfer medium (just like optical pulses through a transmission line cable), or electrical messages transferred through wires.

The computer readable program instructions expressed herein can be downloaded from a computer readable storage medium to each of the extrapolated/processed power grid lines, or downloaded to an external computer or external storage power grid line via a wireless network, like the internet, a local area network, a wide area network, and/or a wireless network. Wireless networks can include copper transfer cables, transmission line transfer, wireless transfer, routers, firewalls, switches, WIFI device computers, and/or edge servers. The wireless network adapter card or wireless network port in each of the extrapolated/processed power grid lines receives computer-readable program instructions from the wireless network and forwards the computer-readable program instructions for storage in the computer-readable accompanying medium in each of the extrapolated/processed power grid lines.

The computer program instructions for performing the operations of the present disclosure can be assembler instructions, instruction set architecture (lSA) instructions, machine-related instructions, microcode, firmware instructions, condition definition values, or source code or object code written in a random convergence of one or more programming languages, including an object oriented programming language such as SDALLQALA, H ++ or the like, as opposed to conventional procedural programming languages, such as the "H" programming language or similar programming languages. The computer readable program instructions can be executed entirely on the client computer, partly on the client computer, as a single software package, partly on the client computer and partly on a remote computer or entirely on the remote computer or server. In a form involving a remote computer, the remote computer can be connected to the client computer through a wireless network, including a local area network (LAb) or a wide area network (UAb), as desired, or can be connected to an external computer (as if an internet service provider were employed to connect through the internet). In some embodiments, each aspect of the present disclosure is achieved by personalizing an electronic circuit, like a programmable logic circuit, a field programmable gate array (disposal platform), or a Programmable Logic Array (PLA), with operating values of computer readable program instructions.

Finally, it should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the above embodiments, it should be understood by those of ordinary skill in the art that: modifications and equivalents may be made to the specific embodiments of the invention without departing from the spirit and scope of the invention, and any modifications and equivalents are intended to be encompassed by the scope of the claims.

Claims (4)

1. A blockchain-based power market abnormal operation condition monitoring method, comprising:

The monitoring platform obtains all real-time demand response sub-instructions through the on-site platform and according to the dynamic adjustable information, and performs block chain uplink on all the real-time demand response sub-instructions to finally form corresponding transaction settlement records;

a method for a monitoring platform to obtain dynamically tunable information via a field platform, comprising:

The monitoring platform located at the first condition is used for executing a first setting stage, wherein the first setting stage comprises:

step 1-1: when the monitoring platform needs to take dynamic adjustable information, forming an information acquisition poll to obtain B1= { B, c, ebub };

Here, B is the identifier of the monitoring platform, c is the identifier of the field platform, ebub is the polling message one, and B1 is used for requesting the field platform to transmit feedback information one to the monitoring platform, and the feedback information one is associated with ebub 1;

Step 1-2: delivering B1 to a site platform;

Step 1-3: if feedback information I is not received in the period one delta U1, transmitting interception polling to the field platform to obtain a UFTU = { b, c }; here, UFTU is configured to require the field platform to transmit back the first listening feedback information to the monitoring platform;

step 1-4: if the interception feedback information I is not received in the period II delta U2, setting the monitoring platform to be in a second state; Δu2 < Δu1;

Taking the moment when the monitoring platform positioned in the first condition transmits B1 to the field platform as a judgment moment I; after the monitoring platform positioned in the first condition transmits B1 to the field platform, whether feedback information I is received in the delta U1 taking the first judgment moment as the starting moment or not can be judged; if the monitoring platform in the first condition receives the feedback information I in the delta U1, the monitoring platform is identified by the field platform as a device which permits the field platform to be read, namely the monitoring platform correctly receives the feedback information I transmitted by the field platform according to the B1; if the monitoring platform at condition one does not receive feedback information one in ΔU1, then the monitoring platform forms UFTU and communicates UFTU1 to the field platform;

The moment when the monitoring platform positioned in the first condition transmits UFTU to the field platform is taken as a judging moment II; after the monitoring platform located in the first condition transmits UFTU a to the field platform, whether interception feedback information I is received in the delta U2 taking the second judgment time as the starting time or not can be judged;

If the first interception feedback information is received in the delta U2, the monitoring platform is a device which is recognized by the field platform as a device which can be read by the field platform;

If the first interception feedback information is not received in the delta U2, the monitoring platform is identified by the field platform as a device for refusing to read the field platform, and then the monitoring platform can be changed to a second state;

The monitoring platform at the second condition is used for executing a second setting stage, and the second setting stage comprises:

Step 2-1: forming an information acquisition query two B2= { B, d, ebub1}, according to the information acquisition query one B1; here, d is the authentication code of the intermediate platform;

Step 2-2: transferring B2 towards the intermediate platform;

step 2-3: receiving feedback information I returned by the middle platform;

After the monitoring platform changes to the second condition, ebub1 can be obtained in B1, and B2 is formed according to the identification code of the monitoring platform corresponding to B2, the identification code of the field platform corresponding to B2 and ebub, namely B2= { B, d, ebub1};

The intermediate platform is a device which is determined to be permitted to be read by the field platform, after the monitoring platform positioned in the second condition transmits B2 to the intermediate platform, the intermediate platform can determine ebub corresponding feedback information I in the B2 and transmit the feedback information I back to the monitoring platform positioned in the second condition, and at the moment, the monitoring platform positioned in the second condition can receive the feedback information I;

The intermediate platform is used for executing a setting stage III, and the setting stage III comprises:

Step 3-1: forming an information acquisition poll three B3= { d, c, ebub1}, according to the information acquisition poll two B2;

step 3-2: delivering B3 towards the site platform;

step 3-3: collecting feedback information I returned by the field platform;

Step 3-4: and returning feedback information to the monitoring platform.

2. The blockchain-based power market abnormal operation condition monitoring method of claim 1, wherein stage two further comprises:

executing the moment of setting the monitoring platform to be in a second condition as a change moment U1;

Obtaining a change time biu2=u1+Δu3; here, Δu3 is a period three set in advance;

From U2, periodically transmitting UFTU a to the field platform; the corresponding timing period of the timed transfer UFTU to the field platform is Δu3;

after each transmission UFTU a, if the first interception feedback information is received in Δu2, setting the monitoring platform to be in a first condition;

when the number of the monitoring platforms is a plurality of, deltaU 3 is determined by the following modes:

obtaining the bandwidth Xje of the intermediate platform and the number Ovn of the monitoring platforms;

taking a listening period group OJNF = { u1, u2, u3...uo }; here, uj is the j-th listening period, j=1, 2, 3..o, L is a preset factor, χ is a correction factor I, δ is a correction factor II, uj+1=η is uj, η is a ratio factor, 0 < L1 +.ltoreq.l2 < 1, L1 is a constant I, L2 is a constant II;

O listening treatments are sequentially executed, and an error frequency group n= { N1, N2, n3...no }; here, nj is the error frequency of the intermediate platform during the execution of the jth snoop treatment, which is to control the monitoring platform to execute the running condition two with uj as Δu3 and hold period four;

The lowest frequency N _njo =njo (N), where njo (N) is a preset equation for obtaining the lowest amount of N;

If n _njo corresponds to a listening period, regarding the listening period corresponding to n _njo as DeltaU 3;

If n _njo corresponds to a number of listening periods, the lowest listening period of the number of listening periods corresponding to n _njo is taken as Δu3.

3. The method of claim 2, wherein B1 and UFTU are both formed and transmitted according to a first communication standard, and the first phase of execution of the monitoring platform at the first status further comprises:

If feedback information I is not received in the period one delta U1, a interception poll is formed according to UFTU1 and a communication standard II to obtain two UFTU 2= { b, c }; the second communication standard is different from the first communication standard; UFTU2 is used for requesting the field platform to transmit the interception feedback information II back to the monitoring platform;

Delivering UFTU to the site platform;

the corresponding steps 1-4 comprise:

After UFTU and UFTU are transmitted, if the first interception feedback information and the second interception feedback information are not received in the second delta U2 period, setting the monitoring platform to be in a second state;

the second stage executed by the corresponding monitoring platform located in the second condition further comprises:

from U2, periodically transmitting UFTU to the field platform; the corresponding timing period of the timed transfer UFTU to the field platform is Δu3;

After each of the above passes UFTU1, if the first snoop feedback is received in Δu2, the monitoring platform is set to condition one, including:

After each transfer UFTU and UFTU2, if either the first or second snoop feedback information is received in ΔU2, the monitoring platform is set to condition one.

4. The blockchain-based power market abnormal operating condition monitoring method of claim 3, wherein UFTU1 corresponds to a highest feedback period of Δu4, Δu4 < Δu2; UFTU2 corresponding to the highest feedback period DeltaU 5, deltaU 2 < DeltaU 5 is less than or equal to DeltaU 2+ DeltaU 3; here, Δu4 is the highest period size from the time of delivering UFTU a to the time of receiving the corresponding listening feedback information one; Δu5 is the highest time period from the time of transmitting UFTU to the time of receiving the corresponding interception feedback information two; the corresponding stage two also comprises:

after setting the monitoring platform to be in the second condition, setting the monitoring platform to be in the first condition if interception feedback information II is received in delta U3 by setting the monitoring platform to be in the second condition;

The identifier is set to be a website, and the field platform is further used for executing the following method:

Collecting B1;

Judging whether B in B1 belongs to a preset website group or not;

if the web address group is not included, feedback information I is returned to the monitoring platform;

the on-site platform is provided with an isolation list, the isolation list is used for storing identification codes refusing to read the on-site platform, and the on-site platform is also used for executing the following method:

if the website is classified into the website group, adding b to the isolation list;

the corresponding stage two is also used for executing the following method:

When the monitoring platform needs to take dynamic adjustable information, forming information acquisition polling to obtain four B4= { B, d, ebub }; here ebub is poll message two;

transferring B4 towards the intermediate platform;

Receiving feedback information II returned by the middle platform; feedback information II corresponds to ebub;

the intermediate platform is also used for executing the following method:

forming an information acquisition query five B5= { d, c, ebub2} according to the information acquisition query four B4;

Delivering B5 towards the site platform;

Collecting feedback information II returned by the field platform;

And returning the feedback information to the monitoring platform.