KR102439722B1 - Weather data-based wireless sensor network node solar energy collection power prediction algorithm - Google Patents

Abstract

The present invention provides a weather data-based wireless sensor network node solar energy collection power prediction algorithm, and can accurately predict the collection power of a wireless sensor network node having a solar energy collection function using a relatively small space and short time. The present invention fully considers the effect of weather changes on the prediction of solar energy collection power, compares and analyzes weather changes and solar energy collection power, and finds the action relationship of the weather change on solar energy collection, so that the weather change is clear accurately predict node solar energy collection power in At the same time, the method can obtain very high prediction precision even in situations where the weather changes significantly and the weather changes stably.

Description

Weather data-based wireless sensor network node solar energy collection power prediction algorithm

The present invention relates to a weather data-based wireless sensor network node solar energy collection power prediction algorithm, and belongs to the wireless sensor network field.

A wireless sensor network (WSN) is a wireless network configured in a self-organizing and multihop manner by mass-stationary or moving sensors. WSN is increasingly favored in the existing development process due to its low cost and high mobility. The application scene can be completed. The basic configuration of WSN is a sensor node, and researchers distribute it to the monitoring area by means of fixed-point injection or random distribution.

A conventional sensor node mainly includes four modules for data collection, data processing, data transmission, and power, among which the power module serves to provide energy to the remaining three modules. Power management in resource-constrained embedded systems remains a daunting challenge, given the mismatched growth trends between batteries and other embedded system assemblies. With WSN's remote scene deployment and lack of reliable power sources, sensors in the network are typically powered by batteries to fulfill their expected missions. Battery-powered WSNs, regardless of their energy efficiency, will eventually fail due to power constraints, regardless of their energy efficiency, unless the battery is replaced. If the network is deployed in harsh environments or in hard-to-reach scenes, battery replacement will have a higher cost and may even become impossible to implement. The technical proposal to solve this problem is to use a battery and environmental energy collection technology together. Commonly available environmental energy that can be collected and used is solar energy, vibration energy, wind energy, and noise. Solar energy is widely used because of its high energy density and easy collection.

When wireless sensor networks are incorporated into energy harvesting capabilities, numerous design issues arise in building the system, such as energy prediction, energy management and routing protocols. Here, energy prediction is also a premise for designing other issues, whether energy management or routing protocols, which must take into account energy consumption when designing, i.e., defining its performance level by the existing available energy. do. The available energy of WSN equipped with energy collection technology includes the remaining energy and the environmental energy collected at a certain time in the future.

Taking WSN energy management with solar energy collection capability as an example, the reason why WSN equipped with environmental energy collection technology can operate continuously in theory is because environmental energy collection technology can supplement the consumption of sensors by collecting environmental energy. However, in reality, it seems that it is very difficult to guarantee the long-term and continuous operation of the WSN for a sensor transmission device with energy collection capability. The main cause is the dependence on uncontrollable solar energy, which is a meteorological component that is difficult to simulate and predict, and changes in time and space cause relatively high short-term fluctuations. Uncertainty in the amount of energy that solar energy is irradiated to the surface causes uncertainty in node collection energy, making it difficult for energy management of WSN to perform energy neutral operation (ENO). less than or equal to the energy. WSN usually uses highly variable environmental energy through the performance level when the motion control system is operating, and ENO can be implemented when the system is always operating at the lowest performance level, but it not only causes a waste of energy, but also causes this The system is also difficult to meet most mission demands; If the system is operated at a relatively high performance level, there is a possibility that the energy collected from the environment will be less than the consumption of the system, and the life of the network may be prematurely terminated. Therefore, rational energy management is one important condition related to the permanent operation of WSN, and the premise of energy management is that the system recognizes the available energy, that is, it can predict the environmental energy collected within a certain time in the future. .

Numerous researchers have proposed prediction algorithms such as EWMA, WCMA, and Pro-Energy for current solar energy. It mainly analyzes previously collected data to predict the short-term collection power in the future. In a stable weather situation, the algorithm has already controlled the prediction error within a very small range, and in particular, WCMA can adapt to simple changes in the weather, but when there is a large change in the weather, it is important to ensure the accuracy of the prediction. very difficult As is known, in most situations, it is very common to change the weather condition from cloudy weather to clear weather within one day, so in the prediction algorithm of solar energy, it is very necessary to examine the real-time weather change. is shown

The present invention provides a weather data-based wireless sensor network node solar energy collection power prediction algorithm, which can accurately predict the collection power of a wireless sensor network node having a solar energy collection function using a relatively small space and short time. In addition, it is possible to accurately predict the solar energy collection power of a node in a situation where there is a clear change in weather, and at the same time obtain a very high prediction precision even in a situation where the weather changes clearly and the weather changes stably.

In detail, the method for predicting solar energy collection power of a wireless sensor network node based on weather data according to the present invention,

Among the monitoring areas, select the real-time weather type data and solar energy collection power data of the adjacent past 5 years, and select the weather types as Sunny (C), Occasionally Cloudy (PC), Cloudy (SC), It is divided into six categories: massive cloud (MCI), cloudy (O), and sleet (RS); Statistical processing of solar energy collection power for different weather types and different time slots, mapping the scaling relationship to the weather type numerical index W based on the scaling relationship between the data of each weather type, and entering step 2 Step 1;

)(

=1,2_…24)를 얻고, 예측 당일의 기상예보데이터 W(d+1,

)와 전날 기상예보데이터 W(d,

)를 대조해 전후 이틀의 날씨 변화 계수 WCS를 얻으며, 단계 3에 진입하는 단계 2;Actual weather forecast data W(d+1,

)(

=1,2 _… 24), and the weather forecast data W(d+1,

) and the previous day's weather forecast data W(d,

) to obtain the weather change coefficient WCS of two days before and after, step 2 entering step 3;

W _t reflects whether or not a significant change in weather occurs and the threshold, and the magnitude is obtained by analyzing the real-time weather type data and node-collected power data, and contrasting WCS and W _t ; If |WCS|<W _t , it is assumed that the weather on the forecast day and the previous day are basically the same, and skip directly to step 4; If |WCS|≥W _t , it is considered that a clear change has occurred in the weather on the day of prediction and the previous day, and skip directly to step 5; step 3;

타임 슬롯의 에너지 수집수치 평균값이고, N=[n₁,n₂,,,n_k]은 하나의 1×k 어레이로서, 예측할 타임 슬롯의 앞 k개 타임 슬롯의 날씨 변화 상황인 데, 그 중 n_j은 계산으로 얻으며; V=[v₁,v₂,,,v_k]은 가중치를 반영하는 데 사용하되, 그 중 V_j은 계산으로 얻고, 최종적으로 예측 당일과 전날을 반영하는 날씨 변화 정도를 계산해 내며(예측 지점의 기왕 수집 파워의 데이터를 통해 확정); 이때 태양에너지 수집 예측값은 직접적인 계산이 가능하며, 그 후 단계 7로 건너뛰는 단계 4;First, we review the situation in which the weather on the day of prediction and the previous day are basically the same, and use the thought of the WCMA algorithm; M _D is the first file in front of the wireless sensor network node

It is the average value of the energy collection value of the time slot, and N=[n ₁ ,n ₂ ,,,n _k ] is one 1×k array, and it is the weather change situation of the k time slots in the front of the time slot to be predicted. n _j is obtained by calculation; V=[v ₁ ,v ₂ ,,,v _k ] is used to reflect weights, of which V _j is obtained by calculation, and finally, the degree of weather change reflecting the forecast day and the previous day is calculated (prediction point). confirmed through the data of previous collection power); In this case, the solar energy collection predicted value can be directly calculated, and then step 4 skips to step 7;

와 k-1개 타임 슬롯의 날씨 변화 정도를 계산해 내고 단계 6으로 진입하는 단계 5;If there is a clear change in the weather on the day of prediction and the previous day, correct the prediction error using the actual weather forecast data on the day of prediction; WF=[wf ₁ ,wf ₂ ,,,wf _k ] is a 1×k array that is used to store and preserve the time slot to be predicted and the weather conditions of the previous k-1 time slots, of which wf _j is calculated through weather forecast data, and finally, when the weather changes significantly, the time slot

Step 5, calculating the degree of weather change in k-1 time slots and entering step 6;

타임 슬롯이 예측해 낸 태양에너지 수집 파워 P(d+1,

)를 계산해 내고 단계 7로 진입하는 단계 6;When there is a significant change in the weather, it is divided into two situations: a situation in which the weather is clearly improved and a situation in which the weather is significantly worse; The effect of these two situations on the collection of solar energy is corrected using constants a and b; Finally, if there is a significant change in the weather, the d+1 day

The solar energy collection power P(d+1, predicted by the time slot)

) is calculated and step 6 enters step 7;

Step 7 to feed back the prediction result to the sensor node and use it to manage energy;

is executed with

Further, in step 2, the calculation formula of the weather change coefficient WCS for two days before and after is,

이며,

is,

)는 제d 일 제i 타임 슬롯의 날씨 유형 지수이다.where W(d,

) is the weather type index of the ith time slot on the dth day.

Furthermore, in step 4, the change in weather conditions is reflected by comparing the numerical change of the energy collection value of the previous time slot on the predicted day and the average value M _D of the energy collection value of the time slot corresponding to the previous D day, but the WCMA algorithm is described as below,

는 제d 일 제

타임 슬롯의 태양에너지 수집 파워의 예측값이고 E(d,

)는 제d일 제

타임 슬롯의 태양에너지 수집 파워의 실제 관찰값이며, α는 가중치 인자이되, α∈[0,1]이며; M_D(d,

)는 앞 D일 타임 슬롯

의 태양에너지 수집 파워의 평균값이고 GAP_y(

)은 당일 타임 슬롯과 지난 D일에 대응되는 타임 슬롯의 날씨 변화 상황을 가리키는 데, 계산공식은,From here,

is the d day

The predicted value of the solar energy harvesting power of the time slot is E(d,

) is the dth day

is the actual observation of the solar energy collection power of the time slot, α is the weighting factor, α∈[0,1]; M _D (d,

) is the previous file timeslot

is the average value of the solar energy collection power of GAP _y (

) indicates the weather change situation of the time slot of the day and the time slot corresponding to the last D day, and the calculation formula is,

이며,

is,

V in the above equation is the weight of the weather change situation of the k time slots before the time slot to be predicted, and as j is larger, the weight v _j also becomes larger,

N is one 1×k array, and records the weather change conditions of the k time slots before the time slot to be predicted. The equation is as follows,

Also, in step 4, n _j is the expression

에 의해 계산된다.

is calculated by

)를 당일 타임 슬롯과 지난 D일에 대응되는 타임 슬롯의 날씨 변화 상황이라고 정의하고 τ는 날씨에 발생된 뚜렷한 변화이며, 또한, τ＞0은 날씨가 뚜렷이 좋아지고, 태양에너지 수집 파워가 대폭 증가된 경우이고, τ＜0은 날씨가 뚜렷이 나빠지고 태양에너지 수집 파워가 감소된 경우이며, 아래의 식과 같고,Further, in steps 5 and 6, GAP _x (

) is defined as the weather change situation of the time slot of the day and the time slot corresponding to the last D day, τ is a distinct change in the weather, and τ > 0 is a marked improvement in the weather and a significant increase in the solar energy collection power. , and τ < 0 is a case where the weather is markedly worse and the solar energy collection power is reduced, as in the following equation,

)는 전후 이틀의 날씨 변화 상황으로서, 구체적으로 아래의 식과 같고, The influence of different weather conditions on solar energy collection power is limited by setting parameters a and b, and parameters a and b are determined based on actual weather conditions and solar energy collection conditions; WC(

) is the weather change situation for the two days before and after, specifically, it is as the following equation,

Here, WF is one 1×k array, which is used to store and preserve the time slot to be predicted and the weather change situation of the previous k-1 time slots, in detail, wf ₁ , wf _{2 ...} The calculation formula for wf _k is as follows.

Also, the incoming V is one 1×k array, which is used to implement the weights; Here, the larger j is, the larger the weight v _j is, that is, the closer it is to the weather change situation of the time slot to be predicted, the more important it is, specifically,

)으로 확정한다.After multiplying WF by V, dividing the sum of V, the final result is the weather change situation WC(

) to be confirmed.

Further, in step 6, the final prediction algorithm is

이며,

is,

Here, w _t is a threshold value that reflects whether the weather has changed significantly, and the size of w _t is obtained through analysis of real-time weather type data and node-collected power data.

The present invention provides a weather data-based wireless sensor network node solar energy collection power prediction algorithm, which can accurately predict the collection power of a wireless sensor network node having a solar energy collection function using a relatively small space and short time. can

The present invention fully considers the effect of weather changes on the prediction of solar energy collection power and compares and analyzes weather changes and solar energy collection power to discover the action relationship of weather changes on solar energy collection. Accurately predict solar energy collection power. At the same time, the method can obtain very high prediction precision even in situations in which the weather changes significantly and the weather changes stably.

1 is a collection power contrast diagram of 24 time slots in winter;
2 shows the weather type index correspondence of different time slots and different weather types in winter;
Figure 3 shows the energy curve of solar energy collection predicted by EWMA and WCMA algorithms;
4 is a flowchart of a solar energy collection power prediction algorithm.

Hereinafter, the technical proposal of the present invention will be described in more detail in combination with the drawings of the specification.

In order to solve the problem that the wireless sensor network node having the solar energy collection function according to the prior art has too low energy management efficiency and the traditional solar energy collection prediction algorithm cannot adapt to the situation in which weather changes occur relatively frequently, the present invention is The weather data of the weather forecast was imported into the prediction algorithm of the solar energy collection power. The method first analyzed in detail the relationship between weather change and node collection power and quantified the effect of weather on the collection power; Next, the weather change was divided into three categories: no significant change, clear improvement in weather, and clear worsening of weather, and the collection power prediction was discussed for each situation. The method can effectively solve the impact of weather changes on the forecasting outcome, improve the precision of the forecasting results, improve the suitability of the algorithm, and achieve very good forecasting effects even in situations with different climatic characteristics.

The method is mainly divided into three parts: first, analyzing the relationship between different climate types and solar energy harvesting power; Second, calculate and analyze the weather change on the day of prediction and the previous day; Third, the predicted value of solar energy collection power is calculated based on different climate change situations.

(1) Analysis of the relationship between different climate types and solar energy collection power

Through previous data analysis, it was concluded that there are also some differences in the degree of influence of seasonal weather types on solar energy collection. By mapping the influencing factors to the weather type index, the influence of the weather type on solar energy collection is reflected.

Select real-time weather type data and node collection power data for the past 5 years of the inner sensor node in a certain situation. First, we divide the weather types into six categories: sunny (C), sunny with occasional clouds (PC), overcast (SC), heavy clouds (MCI), overcast (O), and sleet (RS). There is a clear difference in the amount of collection at different times of the day. One hour is one time slot, and the day is divided into 24 time slots. Next, solar energy collection message statistics are processed for different weather types and different time slots (FIG. 1 is a comparison diagram of the collection power of 24 winter time slots). Finally, the scale relationship is mapped to a weather type index based on the scale relationship between each weather type data. As shown in FIG. 1 , the collection amount of time slots other than the rising and setting of the sun has a very clear relationship with the weather type, so the weather type index of the 11th to 17th time slots is a multiplier relationship between each weather type data, and the remaining time The slot's weather type index is the average of all time slots. Since the amount of data for cloudy weather is large, the weather type index W is set to a unit of 1, and the remaining weather type indexes are converted into equivalents on the basis of cloudy weather. FIG. 2 shows the correspondence relationship of weather type indexes of different time slots and different weather types in winter in a certain situation.

(2) Calculation and analysis of weather changes on the forecast day and the previous day

The EWMA algorithm has relatively high accuracy in the situation where the weather at the forecasting point does not change by default, but the WCMA algorithm corrects the disadvantage that the EWMA algorithm cannot adapt to the weather change, so that the algorithm can predict the weather with relatively high precision. made to have However, if there is a significant change in the weather at the forecast point, such as a cloudy day turning into a sunny day, WCMA still has a relatively high error. The idea of the present invention is to improve the disadvantages of EWMA and WCMA incapable of adapting to a distinct change in the forecast point weather by introducing real-time weather on the network based on WCMA.

)의 계산은 다양한 측면을 검토해야 한다. 예측 당일이 전날의 날씨 상황에 대비해 기본상 동일, 뚜렷한 변화 및 심각한 변화 등이 나타난 경우, 태양에너지의 수집이 다양한 변화가 발생되도록 하지만, 날씨 상황과 태양에너지의 수집 파워 또한 간단한 선형 관계를 구성하지 않으므로, 상황별로 검토해야 한다. 이 기초 상에서, 예측 당일과 전날의 날씨 상황 변화를 구별하는 방안을 검토해야 한다. 기왕 데이터 분석을 통해 하루 날씨 상황의 좋고 나쁨 또는 태양에너지 수집 파워의 높낮이를 결정하는 주요 요소는 정오와 오후 시간대의 날씨 상황이라는 것을 발견하였다. 정오와 오후 시간대의 날씨 상황이 맑은 날씨인 경우에는 당일에 수집된 태양에너지가 비교적 높으며; 이에 반해, 정오와 오후 시간대의 날씨 상황이 흐리었거나 또는 비가 내리는 경우에는 당일의 태양에너지 수집 파워가 아주 낮다. 따라서, 새로운 변수인 WCS를 인입해 예측 당일과 전날의 날씨 변화를 반영하는 데, 상세하게는 아래의 공식(1)과 같고,Since the weather conditions make various changes, the weather modulator GAP (

) calculation should consider various aspects. When the forecasting day is basically the same, a clear change, or a serious change is shown in relation to the weather situation of the previous day, the collection of solar energy causes various changes, but the weather situation and the collection power of solar energy also do not constitute a simple linear relationship. Therefore, it should be considered on a case-by-case basis. On this basis, it is necessary to consider how to distinguish the change in weather conditions on the day of prediction and the day before. Through the previous data analysis, it was found that the main factor determining the good or bad of the day's weather conditions or the level of solar energy collection power was the weather conditions in the noon and afternoon time zones. When the weather conditions in the noon and afternoon hours are clear, the solar energy collected on the day is relatively high; On the other hand, when the weather conditions at noon and afternoon are cloudy or raining, the solar energy collection power of the day is very low. Therefore, a new variable, WCS, is introduced to reflect the weather change on the forecast day and the previous day.

값 또한 확실하지 않다. W(d,

)는 제d 일 제i 타임 슬롯의 날씨 유형 지수이다.Since different scenes have different latitudes, in formula (1)

The value is also uncertain. W(d,

) is the weather type index of the ith time slot on the dth day.

(3) Calculation of solar energy collection power forecasts based on different weather conditions:

After distinguishing between the different weather changes, we need to examine the detailed calculation methods for these changes.

3 shows the energy curves predicted by the EWMA and WCMA algorithms and the average error per day (1 hour per time slot). According to the analysis, the WCMA algorithm reduced the prediction error compared to the EWMA algorithm, but it was concluded that a relatively large error still occurs when the weather change is clear. Through a large-scale experiment on the WCMA algorithm (the weight α during the experiment is fixed at 0.5), the algorithm found that the prediction error for different weather conditions was different. As a comparison, the weather conversion from sunny to cloudy weather has a very large forecast error; Weather that converts from cloudy to sunny weather has a relatively large forecast error; It was found that the forecast error is very small when the weather conditions for the two days after the day are basically the same. Therefore, considering the classification of different weather change situations, it is mainly divided into two categories, a case in which a clear change in weather occurs and a case in which a clear change in weather does not occur, and is denoted as GAP _X and GAP _y , respectively.

① First, the calculation method of GAP _X in a relatively complex situation, that is, when a clear change in weather occurs, will be described. Based on the above analysis, the weather conditions of the two days before and after are further subdivided into two, respectively, a situation in which the weather change is severe and the solar energy collection power is greatly increased, and a situation where the weather change is severe and the solar energy collection power is greatly reduced. For convenience of explanation, as shown in Equation (2), τ is defined as a situation in which a marked change in weather occurs, and τ > 0 is defined as a situation in which the weather is significantly improved and the solar energy collection power is greatly increased, , τ<0 is defined as a situation in which the weather is markedly bad and the solar energy collection power is greatly reduced. Same as formula (2).

)는 전후 이틀의 날씨 변화 상황으로서, 구체적으로 공식 (3)과 같다. The effects of different weather conditions on solar energy collection power are limited by setting parameters a and b, but parameters a and b are determined based on actual weather conditions and solar energy collection conditions. WC(

) is the weather change situation for the two days before and after, specifically as in Formula (3).

Here, WF is one 1×k array, which is used to store and preserve the time slot to be predicted and the weather change situation of the previous k-1 time slots, in detail, wf ₁ ,wf ₂ ,,,wf _k The calculation formula of is the same as Formula (4) to Formula (5),

When the weather condition of the time slot to be predicted is reflected through the time slot to be predicted and the weather change condition of the preceding k-1 time slots, one more problem to consider is the time that wf ₁ ,wf ₂ ,,,wf _k will predict. Since the influence on the weather condition of the slot is different and it is obvious that the closer to the weather change condition of the time slot to be predicted, the more important, so the concept of weight should be introduced. V is still a 1xk array, which is used to implement the weights. Here, as j is large, the weight v _j also increases, that is, the closer the weather change situation of the time slot to be predicted, the more important it is, and specifically, it is as in Formulas (6) to (7).

)으로 확정한다. After multiplying WF by V, dividing the sum of V, the final result is the weather change situation WC(

) to be confirmed.

② Next, the calculation of GAP _y is reviewed in a situation where there is no significant change in the weather. If the weather conditions for the two days after the same day are both sunny or cloudy, the energy value collected by the node does not change significantly, but it does not mean that there is no change. Minor differences may occur. At this time, by selecting the mapping of the WCMA algorithm and comparing the numerical change of the energy collection value of the previous time slot on the day of prediction and the average value of the energy collection value of the time slot corresponding to the previous D day, M _D , the weather situation To reflect the change of , the WCMA algorithm is described as follows,

는 제d 일 제

타임 슬롯의 태양에너지 수집 파워의 예측값이고

는 제d일 제

타임 슬롯의 태양에너지 수집 파워의 실제 관찰값이며, α는 가중치 인자이되, α∈[0,1]이다. M_D(d,

)는 앞 D일 타임 슬롯

의 태양에너지 수집 파워의 평균값이고 GAP_y(

)은 당일 타임 슬롯과 지난 D일에 대응되는 타임 슬롯의 날씨 변화 상황을 가리키는 데, 구체적으로 공식 (9) 내지 (10)과 같다,From here,

is the d day

It is the predicted value of the solar energy collection power of the time slot.

is the d day

It is the actual observed value of the solar energy collection power of the time slot, where α is a weighting factor, but α∈[0,1]. M _D (d,

) is the previous file timeslot

is the average value of the solar energy collection power of GAP _y (

) indicates the weather change situation of the time slot of the day and the time slot corresponding to the last D day, specifically as in formulas (9) to (10),

V in Equation (10) is a weight of the weather change situation of k time slots in front of the time slot to be predicted. As j increases, the weight v _j also increases, as in Equations (6) to (7). N is one 1×k array, in which the weather change conditions of the k time slots in the front of the time slot to be predicted are recorded, as in Equations (11) to (12).

The final prediction algorithm is as Equation (13),

Here, W _t is a threshold that reflects whether or not a clear change in weather has occurred, and the size of W _t is obtained by analyzing the real-time weather type data and node-collected power data.

This method is mainly a specific process for predicting solar energy collection power.

Solar energy collection power prediction: Figure 4 is a solar energy collection power flow chart, detailed execution steps are as follows.

Step 1: Select real-time weather type data and solar energy collection power data of the nearest past 5 years from the monitoring area, and set the weather type as sunny (C), sunny with occasional cloudy (PC), and cloudy (SC), respectively. ), heavy cloud (MCI), cloudy (O), and sleet (RS). The solar energy collection power of different weather types and different time slots is statistically processed, and the scale relationship is mapped to the weather type numerical index W based on the scale relationship between the data of each weather type, and step 2 is entered.

)(

=1,2_…24)를 얻고, 예측 당일의 기상예보데이터 W(d+1,

)와 전날 기상예보데이터 W(d,

)를 대조해 전후 이틀의 날씨 변화 계수WCS를 얻으며, 단계 3에 진입한다.Step 2: Actual weather forecast data W(d+1,

)(

=1,2 _… 24), and the weather forecast data W(d+1,

) and the previous day's weather forecast data W(d,

) to obtain the weather change coefficient WCS of the two days before and after, and enter step 3.

Step 3: W _t reflects whether or not a significant change in weather occurs and the threshold, and the magnitude is obtained by analyzing the real-time weather type data and node-collected power data, but contrasts WCS and W _t . If |WCS|<W _t , it is assumed that the weather on the forecast day and the previous day are basically the same, and skip directly to step 4; If |WCS|≥W _t , it is assumed that a significant change has occurred in the weather on the day of prediction and on the previous day, and skip directly to step 5.

타임 슬롯의 에너지 수집수치 평균값이고, N=[n₁,n₂,,,n_k]은 하나의 1×k어레이로서, 예측할 타임 슬롯의 앞 k개 타임 슬롯의 날씨 변화 상황을 기록하는 데, 그 중 n_i은 공식(12)로 계산해 얻는다. V=[v₁,v₂,,,v_k]은 가중치를 반영하는 데 사용하되, 그 중 v_j는 공식(7)로 계산해 얻고, 최종적으로 공식(10)으로 예측 당일과 전날을 반영하는 날씨 변화 정도를 계산해 낸다.(예측 지점의 기왕 수집 파워 데이터를 통해 확정) 이 때의 태양에너지 수집 예측값은 직접 공식(5)로 계산할 수 있으며, 그 후 단계 7로 건너뛴다.Step 4: First, review the situation in which the weather on the forecast day and the previous day are basically the same, and use the ideas of the WCMA algorithm. As shown in formula (9), M _D is the first D in front of the wireless sensor network node.

It is the average value of the energy collection value of the time slot, and N=[n ₁ ,n ₂ ,,,n _k ] is one 1×k array, which records the weather change situation of the k time slots in the front of the time slot to be predicted, Among them, n _i is obtained by calculating with formula (12). V=[v ₁ ,v ₂ ,,,v _k ] is used to reflect the weight, of which v _j is obtained by calculating with formula (7), and finally using formula (10) to reflect the prediction day and the previous day. Calculate the degree of change in the weather (confirmed through the previously collected power data at the prediction point). The predicted value of solar energy collection at this time can be directly calculated by formula (5), and then skip to step 7.

와 앞 k-1개 타임 슬롯의 날씨 변화 정도를 계산해 내고 단계 6으로 진입한다.Step 5: If there is a clear change in the weather on the forecast day and the previous day, the forecast error is corrected using the actual weather forecast data on the forecast day. WF=[wf ₁ ,wf ₂ ,,,wf _k ] is a 1×k array, which is used to store and preserve the time slot to be predicted and the weather conditions of the previous k-1 time slots, of which wf _j is calculated through weather forecast data, and is as detailed in formula (5), and finally, when the weather changes significantly according to formula (3),

and calculate the degree of weather change in the preceding k-1 time slots, and proceed to step 6.

타임 슬롯이 예측해 낸 태양에너지 수집 파워 P(d+1,

)를 계산해 내고 단계 7로 진입한다.Step 6: When there is a significant change in the weather, it is divided into two situations: a situation in which the weather has significantly improved and a situation where the weather has significantly deteriorated. The effects of these two situations on the collection of solar energy are different, and as shown in Equation (2), they are corrected using the constants a and b. Finally, using formula (13), if there is a significant change in the weather, the d+1 day

The solar energy collection power P(d+1, predicted by the time slot)

) and proceed to step 7.

Step 7: The prediction result is fed back to the sensor node and used to manage energy.

The above is only a preferred embodiment of the present invention, and the scope of protection of the present invention is not limited by the embodiment, but equivalents implemented by those skilled in the art of the present invention based on the content disclosed in the present invention All modifications or changes are included within the scope of protection described in the claims.

Claims (5)

delete A method for predicting solar energy collection power of a wireless sensor network node based on weather data,
Among the monitoring areas, real-time weather type data and solar energy collection power data of the past 5 years are selected, and the weather types are respectively sunny (C), sunny with occasional clouds (PC), with clouds (SC), It is divided into six categories: massive cloud (MCI), cloudy (O), and sleet (RS); Statistical processing of solar energy collection power of different weather types and different time slots, mapping the scaling relationship to the weather type numerical index W based on the scaling relationship between the data of each weather type, Step 2 Step 1 of entering into;
Actual weather forecast data W(d+1,

)(

=1,2 _… 24), and the weather forecast data W(d+1,

) and the previous day's weather forecast data W(d,

), to obtain the weather change coefficient WCS of two days before and after, step 2 entering step 3;
W _t reflects whether or not a significant change in weather occurs and the threshold, and the magnitude is obtained by analyzing the real-time weather type data and node-collected power data, and contrasts WCS and W _t ; If |WCS|<W _t , it is assumed that the weather on the forecast day and the previous day are basically the same, and skip directly to step 4; If |WCS|≥W _t , it is considered that a clear change has occurred in the weather on the day of prediction and the previous day, and skip directly to step 5; step 3;
First, the forecasting day and the previous day's weather are basically the same, and the WCMA algorithm is used; M _D is the first file in front of the wireless sensor network node

It is the average value of the energy collection value of the time slot, and N=[n ₁ ,n ₂ ,,,n _k ] is one 1×k array, and it is the weather change situation of the k time slots in the front of the time slot to be predicted. n _j is obtained by calculation; V=[v ₁ ,v ₂ ,,,v _k ] is used to reflect the weights, where V _j is obtained by calculation and finally calculates the degree of weather change reflecting the forecast day and the previous day (prediction point) confirmed through the data of previous collection power); In this case, the solar energy collection predicted value can be directly calculated, and then step 4 skips to step 7;
If there is a clear change in the weather on the day of prediction and the previous day, correct the prediction error using the actual weather forecast data on the day of prediction; WF=[wf ₁ ,wf ₂ ,,,wf _k ] is a 1×k array used to store and preserve the time slot to be predicted and the weather conditions of the preceding k-1 time slots, where wf _j is calculated from weather forecast data, and when the weather finally changes significantly, the time slot on the forecast day

Step 5, calculating the degree of weather change in k-1 time slots, and entering step 6;
When there is a significant change in the weather, it is divided into two situations: a situation in which the weather is clearly improved and a situation in which the weather is significantly worse; The effect of these two situations on the collection of solar energy is corrected using constants a and b; Finally, if there is a significant change in the weather, the d+1 day

The solar energy collection power P(d+1, predicted by the time slot)

) is calculated, step 6 to enter step 7; and
Step 7, wherein the prediction result is fed back to the sensor node and used to manage energy;
In step 2 above, the formula for calculating the weather change coefficient WCS for two days before and after is,

is,
where W(d,

) is a weather data-based wireless sensor network node solar energy collection power prediction method, characterized in that it is the weather type index of the d-day i-th time slot. 3. The method of claim 2,
In step 4, the change in weather conditions is reflected by comparing the numerical change of the energy collection value of the previous time slot on the predicted day and the average value M _D of the energy collection value of the time slot corresponding to the previous D day, but the WCMA algorithm is as follows are listed together,

From here,

is the d day

The predicted value of the solar energy collection power of the time slot, E(d,

) is the dth day

is the actual observation of the solar energy collection power of the time slot, α is the weighting factor, α∈[0,1]; M _D (d,

) is the previous file timeslot

is the average value of the solar energy collection power of GAP _y (

) indicates the weather change situation of the time slot of the day and the time slot corresponding to the last D day, and the calculation formula is as follows,

V in the above formula is the weight of the weather change situation of the k time slots in the front of the time slot to be predicted. As j is larger, the weight v _j also increases.

N is one 1×k array, and records the weather change conditions of the k time slots in the front of the time slot to be predicted, the formula is as follows,

Also, in step 4, n _j is the formula

Weather data-based wireless sensor network node solar energy collection power prediction method, characterized in that calculated through. 3. The method of claim 2,
In steps 5 and 6 above, GAP _x (

) is defined as the weather change situation of the time slot of the day and the time slot corresponding to the last D day, τ is a distinct change in the weather, and τ > 0 is the time slot for the day and the time slot corresponding to the last D day. case, τ<0 is the case where the weather is clearly worse and the solar energy collection power is reduced, as in the following equation,

The influence of different weather conditions on solar energy collection power is limited by setting parameters a and b, and parameters a and b are determined based on actual weather conditions and solar energy collection conditions; WC(

) is the weather change situation for the two days before and after, specifically, it is as the following equation,

Here, the WF is a 1×k array, which is used to store and preserve the time slot to be predicted and the weather change situation of the previous k-1 time slots. Specifically, wf ₁ , wf _{2 ...} The formula for calculating wf _k is as follows,

Also, the incoming V is one 1×k array, which is used to implement the weights; Here, the larger j is, the larger the weight v _j is, that is, the closer it is to the weather change situation of the time slot to be predicted, the more important it is, specifically,

After multiplying WF by V, dividing the sum of V, the final result is the weather change situation WC(

), a method of predicting solar energy collection power of a wireless sensor network node based on weather data, characterized in that it is determined. 3. The method of claim 2,
In step 6, the formula of the final prediction algorithm is as follows,

Here, w _t is a threshold value that reflects whether the weather has changed significantly, and the size of w _t is a weather data-based wireless sensor, characterized in that it is obtained through analysis of real-time weather type data and node-collected power data. Network node solar energy collection power prediction method.

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