1. 06/2000 Short-term load forecasting 1 SHORT TERM LOAD FORECASTING USING NEURAL NETWORKS AND FUZZY LOGIC George G Karady
Arizona State University
2. 06/2000 Short-term load forecasting 2 Short Term Load Forecasting�Content Overview of Short term load forecasting
Introduction
Definitions and expected results
Importance of Short-term load forecasting
Impute data and system parameters required for load forecasting
Concept
Major load forecasting techniques
Concept of STLF model Development
Statistical methods
(Multiply liner regression,
stochastic time series e.t.c)
3. 06/2000 Short-term load forecasting 3 Short Term Load Forecasting�Content Artificial Neural Networks
Building block: a feed forward network
Load forecasting engine
Results
Numerical example
Fuzzy logic and evolutionary programming
4. 06/2000 Short-term load forecasting 4 Overview of Short Term Load Forecasting (STLF)�
5. 06/2000 Short-term load forecasting 5 Introduction The electrical load increases about 3-7% per year for many years.
The long term load increase depends on the population growth, local area development, industrial expansion e.t.c.
The short term load variation depends on weather, local events, type of day (Weekday or Holiday or Weekend) e.t.c.
6. 06/2000 Short-term load forecasting 6 Introduction The building of a power plant requires:
10 years (Nuclear)
6 years (Large coal-fired)
3 years (combustion turbine)
The electric system planing needs the forecast of the load for several years.
Typically the long term forecast covers a period of 20 years
7. 06/2000 Short-term load forecasting 7 Introduction The planning of maintenance, scheduling of the fuel supply etc. calls for medium term load forecast .
The medium term load forecast covers a period of a few weeks.
It provides the peak load and the daily energy requirement
8. 06/2000 Short-term load forecasting 8 Introduction The number of generators in operation, the start up of a new unit depends on the load.
The day to day operation of the system requires accurate short term load forecasting.
9. 06/2000 Short-term load forecasting 9 Introduction Typically the short term load forecast covers a period of one week
The forecast calculates the estimated load for each hours of the day (MW).
The daily peak load. (MW)
The daily or weekly energy generation. (MWh)
10. 06/2000 Short-term load forecasting 10 Introduction The utilities use three types of load forecasting:
Long term (e.g. 20 years)
Medium term. (e.g. 3-8 weeks)
Short term (e.g. one week)
This lecture presents the short term load forecasting techniques
11. 06/2000 Short-term load forecasting 11 Definitions and Expected Results�(Big picture) The short term load forecasting provides load data for each hour and cover a period of one week.
The load data are:
hourly or half-hourly peak load in kW
hourly or half-hourly values of system energy in kWh
Daily and weekly system energy in kWh
12. 06/2000 Short-term load forecasting 12 Definitions and Expected Results�(Big picture) The short term load forecasting is performed daily or weekly.
The forecasted data are continuously updated.
Typical short-term, daily load forecast is presented in the Table in the next page. (Salt River Project, SRP)
13. 06/2000 Short-term load forecasting 13 Definitions and Expected Results�(Big picture) Typical short-term, daily load forecast from Salt River Project. Hourly Load in MW
14. 06/2000 Short-term load forecasting 14 Definitions and Expected Results�(Big picture) Typical short-term, daily load forecast from Salt River Project. Hourly Load in MW
15. 06/2000 Short-term load forecasting 15 Importance of Short-term Load Forecasting Provide load data to the dispatchers for economic and reliable operation of the local power system.
The timeliness and accuracy of the data affects the cost of operation.
Example: The increase of accuracy of the forecast by 1% reduced the operating cost by L 10M in the British Power system in 1985
16. 06/2000 Short-term load forecasting 16 Importance of Short-term Load Forecasting The forecasted data are used for:
Unit commitment.
selection of generators in operation,
start up/shut down of generation to minimize operation cost
Hydro scheduling to optimize water release from reservoirs
Hydro-thermal coordination to determine the least cost operation mode (optimum mix)
17. 06/2000 Short-term load forecasting 17 Importance of Short-term Load Forecasting The forecasted data are used for:
Interchange scheduling and energy purchase.
Transmission line loading
Power system security assessment.
Load-flow
transient stability studies
using different contingencies and the predicted loads.
18. 06/2000 Short-term load forecasting 18 Importance of Short-term Load Forecasting These off-line network studies:
detect conditions under which the system is vulnerable
permit preparation of corrective actions
load shedding,
power purchase,
starting up of peak units,
switching off interconnections, forming islands,
increase spinning and stand by reserve
19. 06/2000 Short-term load forecasting 19 Impute Data and System Parameters for Load Forecasting The system load is the sum of individual load.
The usage of electricity by individuals is unpredictable and varies randomly.
The system load has two components:
Base component
Randomly variable component
20. 06/2000 Short-term load forecasting 20 Impute Data and System Parameters for Load Forecasting The factors affecting the load are:
economical or environmental
time
weather
Unforeseeable random events
21. 06/2000 Short-term load forecasting 21 Impute Data and System Parameters for Load Forecasting Economical or environmental factors
Service area demographics (rural, residential)
Industrial growth.
Emergence of new industry, change of farming
Penetration or saturation of appliance usage
Economical trends (recession or expansion)
Change of the price of electricity
Demand side load management
22. 06/2000 Short-term load forecasting 22 Impute Data and System Parameters for Load Forecasting The time constraints of economical or environmental factors are slow,
measured in years.
This factors explains the regional variation of the load model (New York vs. Kansas)
The load model depends on these slow changing factors and has to be updated periodically
23. 06/2000 Short-term load forecasting 23 Impute Data and System Parameters for Load Forecasting Time Factors affecting the load
Seasonal variation of load (summer, winter etc.). The load change is due to:
Change of number of daylight hours
Gradual change of average temperature
Start of school year, vacation
Calls for a different model for each season
24. 06/2000 Short-term load forecasting 24 Impute Data and System Parameters for Load Forecasting Typical Seasonal Variation of Load
Summer peaking utility
25. 06/2000 Short-term load forecasting 25 Impute Data and System Parameters for Load Forecasting Time Factors affecting the load
Daily variation of load. ( night, morning,etc)
26. 06/2000 Short-term load forecasting 26 Impute Data and System Parameters for Load Forecasting Weekly Cyclic Variation
Saturday and Sunday significant load reduction
Monday and Friday slight load reduction
Typical weekly load pattern:
27. 06/2000 Short-term load forecasting 27 Impute Data and System Parameters for Load Forecasting Time Factors affecting the load
Holidays (Christmas, New Years)
Significant reduction of load
Days proceeding or following the holidays also have a reduced load.
Pattern change due to the tendency of prolonging the vacation
28. 06/2000 Short-term load forecasting 28 Impute Data and System Parameters for Load Forecasting Weather factors affecting the load
The weather affects the load because of weather sensitive loads:
air-conditioning
house heating
irrigation
29. 06/2000 Short-term load forecasting 29 Impute Data and System Parameters for Load Forecasting Weather factors affecting the load
The most important parameters are:
Forecasted temperature
Forecasted maximum daily temperature
Past temperature
Regional temperature in regions with
diverse climate
30. 06/2000 Short-term load forecasting 30 Impute Data and System Parameters for Load Forecasting Weather Factors Affecting the Load
The most important parameters are:
Humidity
Thunderstorms
Wind speed
Rain, fog, snow
Cloud cover or sunshine
31. 06/2000 Short-term load forecasting 31 Impute Data and System Parameters for Load Forecasting Random Disturbances Effects on Load
Start or stop of large loads (steel mill, factory, furnace)
Widespread strikes
Sporting events (football games)
Popular television shows
Shut-down of industrial facility
32. 06/2000 Short-term load forecasting 32 Impute Data and System Parameters for Load Forecasting The different load forecasting techniques use different sets of data listed before.
Two -three years of data is required for the validation and development of a new forecasting program.
The practical use of a forecasting program requires a moving time window of data
33. 06/2000 Short-term load forecasting 33 Impute Data and System Parameters for Load Forecasting The moving time window of data requires:
Data covering the last 3-6 weeks
Data forecasted for the forecasting period, generally one week
34. 06/2000 Short-term load forecasting 34 Impute Data and System Parameters for Load Forecasting The selection of long periods of historical data eliminates the seasonal variation
The selection of short periods of historical data eliminates the processes that are no longer operative.
35. 06/2000 Short-term load forecasting 35 Impute Data and System Parameters for Load Forecasting The forecasting is a continuous process.
The utility forecasts the load of its service area.
The forecaster
prepares a new forecast for everyday and
updates the existing forecast daily
The data base is a moving window of data
36. 06/2000 Short-term load forecasting 36 Major Load Forecasting� Techniques Statistical methods
Artificial Neural Networks
Fuzzy logic
Evolutionary programming
Simulated Annealing and expert system
Combination of the above methods
37. 06/2000 Short-term load forecasting 37 Major Load Forecasting� Techniques The statistical methods will be discussed briefly to explain the basic concept of the load forecasting
This lecture concentrates on load forecasting methods using neural networks and fuzzy logic
38. 06/2000 Short-term load forecasting 38 Concept of STLF Model Development Model selection
Calculation and update of model parameters
Testing the model performance
Update/modification of the model if the performance is not satisfactory
39. 06/2000 Short-term load forecasting 39 Concept of STLF Model Development Model selection
Selection of mathematical techniques that match with the local requirements
Calculation and update of model parameters
This includes the determination of the constants and
selection of the method to update the constants values as the circumstance varies. (seasonal changes)
40. 06/2000 Short-term load forecasting 40 Concept of STLF Model Development Testing the model performance
First the model performance has to be validated using 2-3 years of historical data
The final validation is the use of the model in real life conditions. The evaluation terms are:
accuracy
ease of use
bad/anomalous data detection
41. 06/2000 Short-term load forecasting 41 Concept of STLF Model Development Update/modification of the model if the performance is not satisfactory
Due to the changing circumstances (regional gross, decline of local industry etc.) the model becomes obsolete and inaccurate,
Model performance, accuracy has to be evaluated continuously
Periodic update of parameters or the change of model structure is needed
42. 06/2000 Short-term load forecasting 42 Artificial Neural Networks�for STLF
43. 06/2000 Short-term load forecasting 43 Artificial Neural Networks�for STLF Several Artificial Neural Network (ANN) based load forecasting programs have been developed.
The following neural networks were tested for load forecasting:
Feed-forward type ANN
Radial based ANN
Recurrent type ANN
44. 06/2000 Short-term load forecasting 44 Building Blocks of � a Feed Forward Network A Feed forward Three-Layered Perceptron Type ANN was selected to demonstrate the short term load forecasting technique.
The selected network forecasts:
Hourly loads
Peak load of the day
Total load of the day.
45. 06/2000 Short-term load forecasting 45 Building Blocks of � a Feed Forward Network The forecasting with neural network will be demonstrated using a feed forward three-layered network to forecast the peak load of the day.
The network has:
one output: (load in kW)
three input: (previous day max. load and temperature, forecasted max. temperature)_
46. 06/2000 Short-term load forecasting 46 Building Blocks of� a Feed Forward Network The structure of the Feed Forward Three-Layered Perceptron Type ANN is presented on the next page.
The network contains:
i = 1.. 3 input layer nodes
j = 1…5 hidden layer nodes
k = 1 output layer nodes
47. 06/2000 Short-term load forecasting 47 Artificial Neural Networks�for STLF
48. 06/2000 Short-term load forecasting 48 Building Blocks of � a Feed Forward Network The inputs are:
X1 previous day max. load
X2 previous day max. temperature
X3 forecasted max. temperature
Wij weight factor between input and hidden layer
wj weight factor between hidden layer and output
49. 06/2000 Short-term load forecasting 49 Building Blocks of � a Feed Forward Network A sigmoid function is placed in the nodes (neurons) of the hidden layer and output node.
The sigmoid equation for an arbitrary Z function is:
Y output :maximum load
50. 06/2000 Short-term load forecasting 50 Building Blocks of � a Feed Forward Network Inputs Xi are multiplied by the connection weights (Wij) and passed on to the neurons in the hidden layer.
The weighted inputs (Xi*Wij) to each neurons are added together and passed through a sigmoid function.
Input of hidden layer neuron 1 is:
51. 06/2000 Short-term load forecasting 51 Building Blocks of � a Feed Forward Network The output Hj of the jth hidden layer node is:
52. 06/2000 Short-term load forecasting 52 Building Blocks of � a Feed Forward Network Inputs Hj are multiplied by the connection weights (wk) and passed on to the neurons in the output layer.
The weighted inputs (Hj*wk) to each output neurons are added together and passed through a sigmoid function.
Input of output neuron is:
53. 06/2000 Short-term load forecasting 53 Building Blocks of� a Feed Forward Network The output Y is:
54. 06/2000 Short-term load forecasting 54 Training of the � Feed Forward Neural Network The described neural network is trained using historical data.
Typical data set contains 2-3 years of load and weather data.
Error back propagation (BP) method is used for the training.
During the learning the weights are adjusted repeatedly.
55. 06/2000 Short-term load forecasting 55 Training of the � Feed Forward Neural Network The output produced by the ANN in response to inputs are repeatedly compared with the correct answers
Each time the weights are adjusted slightly by beck-propagating the error at the output layer through the ANN
Equations for the training are presented in the next page
56. 06/2000 Short-term load forecasting 56 Training of the � Feed Forward Neural Network The equations used for the training are:
Weight is between input and hidden layer:
Weight is between hidden layer and output:
57. 06/2000 Short-term load forecasting 57 Training of the � Feed Forward Neural Network In the equations:
Yactual is the true value of the output load
e is learning factor (0.3-0.8)
n is the number of learning cycles
Xj is the input value belongs to Yactual
A numerical example demonstrates the use of neural forecasting method.
58. 06/2000 Short-term load forecasting 58 Training of the � Feed Forward Neural Network The over training has to be avoided using the cross validation method:
The training set is divided into two parts. (Part 1 : two years data, Part 2: one year data)
Part 1 is used to train the network, by passing the data through the network.
Few hundred times pass represents a training period.
59. 06/2000 Short-term load forecasting 59 Training of the � Feed Forward Neural Network The over training of the network has to be avoided:
Part 2 is used to check the effectiveness of the training.
After each training period the error is calculated when the network is supplied by the input data of Part 2.
The increase of error indicates over training, when the training has to be stopped
60. 06/2000 Short-term load forecasting 60 Load Forecasting Engine The EPRI developed a Load Forecasting Engine using 24 Neural networks.
One network forecasts the load for each hour of the day.
The networks are grouped into four (4) categories depending on time of the day.
The categories have different inputs.
61. 06/2000 Short-term load forecasting 61 Load Forecasting Engine
62. 06/2000 Short-term load forecasting 62 Load Forecasting Engine The four categories are:
Category 1. Nine neural networks. Forecasts the load between 1-9AM .
Category 2. Nine neural networks. Forecasts the load between 10AM -2PM and 7 -10PM .
Category 3. Four neural networks. Forecasts the load between 3-6 PM .
Category 4. Two neural networks. Forecasts the load between 11-12 PM .
63. 06/2000 Short-term load forecasting 63 Load Forecasting Engine The inputs in four categories are:
Category 1. Forecast for early morning
general input
load in the last three-four hours
temperature in the last three-four hours
Category 2. Forecast for off peak hours
general input
forecast temperature of previous hours
yesterday’s load and temperature of hours close to this hours
64. 06/2000 Short-term load forecasting 64 Load Forecasting Engine The inputs in four categories are:
Category 3. Forecast for afternoon peak hours
general input
forecast temperatures of previous and feature hours close to this hours.
yesterday’s load and temperature of hours close to this hours
Category 4. Forecast for late night hours
general input
forecast temperatures for the four proceeding hours
65. 06/2000 Short-term load forecasting 65 Load Forecasting Engine The general input variables are
same hour load, temperature and humidity of one day ago. (3)
same hour load, temperature and humidity of two days ago. (3)
same hour load and temperature seven (7) days ago (2)
66. 06/2000 Short-term load forecasting 66 Load Forecasting Engine The general input variables are (continuation):
same hour forecast temperature and relative humidity of the next day (2)
day of the week index (Sunday 01, Monday 02 etc.)
67. 06/2000 Short-term load forecasting 67 Load Forecasting Engine The load forecasting engine has one output for the hourly load
The extended forecast uses the forecasted values. E.g. The two-day ahead forecast uses values obtained by the one-day ahead forecast.
The forecast can be updated each hour using the recent load and weather data
68. 06/2000 Short-term load forecasting 68 Load Forecasting Engine The weights in the neural network are adjusted daily.
The retraining uses the actual load and weather data of the past few days.
The retraining helps to follow the trends, changes of weather patter e.t.c
69. 06/2000 Short-term load forecasting 69 Load Forecasting For Holidays The load during the holidays has different patterns and is significantly reduced.
The forecast is inaccurate because of the small number of historical data.
The holiday is treated as
Saturday if the shopping centers are open
Sunday if the shopping centers are not open
70. 06/2000 Short-term load forecasting 70 Hourly Weather Forecast The weather service provides forecasts for:
daily maximum and minimum temperature
daily maximum and minimum relative humidity
rain and fog
maximum wind speed
No hourly data are provided.
71. 06/2000 Short-term load forecasting 71 Hourly Weather Forecast EPRI developed an hourly temperature and humidity forecasting engine.
Single neural network with
28 inputs :
hourly temperature of the previous day)
high and low temperature of the two previous day
24 outputs: expected hourly temperatures.
72. 06/2000 Short-term load forecasting 72 Load Forecasting Results
73. 06/2000 Short-term load forecasting 73 Load Forecasting Results
74. 06/2000 Short-term load forecasting 74 Load Forecasting Results
75. 06/2000 Short-term load forecasting 75 Appendix 1 Derivation of Learning Algorithm
76. 06/2000 Short-term load forecasting 76 Derivation of Learning Algorithm The output of the hidden and output layer and the error function are:
77. 06/2000 Short-term load forecasting 77 Derivation of Learning Algorithm The update of the weight factors require iteration
For the calculation of the derivative the following substitutions are used
78. 06/2000 Short-term load forecasting 78 Derivation of Learning Algorithm After substitutions the equations are:
79. 06/2000 Short-term load forecasting 79 Derivation of Learning Algorithm The derivation of the error function results in :
The derivative of the u function is:
80. 06/2000 Short-term load forecasting 80 Derivation of Learning Algorithm The derivative of the output function is:
81. 06/2000 Short-term load forecasting 81 Derivation of Learning Algorithm The derivation of the auxiliary function Y2 gives:
The derivative of Y1 function is:
82. 06/2000 Short-term load forecasting 82 Derivation of Learning Algorithm Substituting the results in the equations :
83. 06/2000 Short-term load forecasting 83 Derivation of Learning Algorithm The rearrangement of the output equation results in :
The final equation for the update of dwj is:
84. 06/2000 Short-term load forecasting 84 Derivation of Learning Algorithm The derivative of the hidden layer function is:
85. 06/2000 Short-term load forecasting 85 Derivation of Learning Algorithm The derivation of the auxiliary function h2 gives:
The derivative of h1 function is:
86. 06/2000 Short-term load forecasting 86 Derivation of Learning Algorithm Substituting the results in the equations :
87. 06/2000 Short-term load forecasting 87 Derivation of Learning Algorithm The rearrangement of the output equation results in :
The final equation for the update of dWij is:
88. 06/2000 Short-term load forecasting 88 Derivation of Learning Algorithm Substituting the results in the equations which is used to iterate the wj value :
89. 06/2000 Short-term load forecasting 89 Derivation of Learning Algorithm The two training algorithms are:
