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1、 目 录part 1 pid type fuzzy controller and parameters adaptive method1part 2 application of self adaptation fuzzy-pid control for main steam temperature control system in power station7part 3 neuro-fuzzy generalized predictive control of boiler steam temperature13part 4 为part3译文:锅炉蒸汽温度模糊神经网络的广义预测控制21p
2、art 1 pid type fuzzy controller and parameters adaptive method wu zhi qiao, masaharu mizumoto abstract: the authors of this paper try to analyze the dynamic behavior of the product-sum crisp type fuzzy controller, revealing that this type of fuzzy controller behaves approximately like a pd controlle
3、r that may yield steady-state error for the control system. by relating to the conventional pid control theory, we propose a new fuzzy controller structure, namely pid type fuzzy controller which retains the characteristics similar to the conventional pid controller. in order to improve further the
4、performance of the fuzzy controller, we work out a method to tune the parameters of the pid type fuzzy controller on line, producing a parameter adaptive fuzzy controller. simulation experiments are made to demonstrate the fine performance of these novel fuzzy controller structures. keywords: fuzzy
5、controller; pid control; adaptive control 1. introduction among various inference methods used in the fuzzy controller found in literatures , the most widely used ones in practice are the mamdani method proposed by mamdani and his associates who adopted the min-max compositional rule of inference ba
6、sed on an interpretation of a control rule as a conjunction of the antecedent and consequent, and the product-sum method proposed by mizumoto who suggested to introduce the product and arithmetic mean aggregation operators to replace the logical and (minimum) and or (maximum) calculations in the min
7、-max compositional rule of inference. in the algorithm of a fuzzy controller, the fuzzy function calculation is also a complicated and time consuming task. tagagi and sugeno proposed a crisp type model in which the consequent parts of the fuzzy control rules are crisp functional representation or cr
8、isp real numbers in the simplified case instead of fuzzy sets . with this model of crisp real number output, the fuzzy set of the inference consequence will be a discrete fuzzy set with a finite number of points, this can greatly simplify the fuzzy function algorithm. both the min-max method and the
9、 product-sum method are often applied with the crisp output model in a mixed manner. especially the mixed product-sum crisp model has a fine performance and the simplest algorithm that is very easy to be implemented in hardware system and converted into a fuzzy neural network model. in this paper, w
10、e will take account of the product-sum crisp type fuzzy controller. 2. pid type fuzzy controller structure as illustrated in previous sections, the pd function approximately behaves like a parameter time-varying pd controller. since the mathematical models of most industrial process systems are of t
11、ype, obviously there would exist an steady-state error if they are controlled by this kind of fuzzy controller. this characteristic has been stated in the brief review of the pid controller in the previous section. if we want to eliminate the steady-state error of the control system, we can imagine
12、to substitute the input (the change rate of error or the derivative of error) of the fuzzy controller with the integration of error. this will result the fuzzy controller behaving like a parameter time-varying pi controller, thus the steady-state error is expelled by the integration action. however,
13、 a pi type fuzzy controller will have a slow rise time if the p parameters are chosen small, and have a large overshoot if the p or i parameters are chosen large. so there may be the time when one wants to introduce not only the integration control but the derivative control to the fuzzy control sys
14、tem, because the derivative control can reduce the overshoot of the system's response so as to improve the control performance. of course this can be realized by designing a fuzzy controller with three inputs, error, the change rate of error and the integration of error. however, these methods w
15、ill be hard to implement in practice because of the difficulty in constructing fuzzy control rules. usually fuzzy control rules are constructed by summarizing the manual control experience of an operator who has been controlling the industrial process skillfully and successfully. the operator intuit
16、ively regulates the executor to control the process by watching the error and the change rate of the error between the system's output and the set-point value. it is not the practice for the operator to observe the integration of error. moreover, adding one input variable will greatly increase t
17、he number of control rules, the constructing of fuzzy control rules are even more difficult task and it needs more computation efforts. hence we may want to design a fuzzy controller that possesses the fine characteristics of the pid controller by using only the error and the change rate of error as
18、 its inputs. one way is to have an integrator serially connected to the output of the fuzzy controller as shown in fig. 1. in fig. 1,andare scaling factors for e and respectively, and fl is the integral constant. in the proceeding text, for convenience, we did not consider the scaling factors. here
19、in fig. 2, when we look at the neighborhood of node point in the e - plane, it follows from (1) that the control input to the plant can be approximated by (1) hence the fuzzy controller becomes a parameter time-varying pi controller, its equivalent proportional control and integral control component
20、s are bk2d and ilk1 p respectively. we call this fuzzy controller as the pi type fuzzy controller (pi fc). we can hope that in a pi type fuzzy control system, the steady-state error becomes zero. to verify the property of the pi type fuzzy controller, we carry out some simulation experiments. before
21、 presenting the simulation, we give a description of the simulation model. in the fuzzy control system shown in fig. 3, the plant model is a second-order and type system with the following transfer function: (2)where k = 16, = 1, and= 0.5. in our simulation experiments, we use the discrete simulatio
22、n method, the results would be slightly different from that of a continuous system, the sampling time of the system is set to be 0.1 s. for the fuzzy controller, the fuzzy subsets of e and d are defined as shown in fig. 4. their cores the fuzzy control rules are represented as table 1. fig. 5 demons
23、trates the simulation result of step response of the fuzzy control system with a pl fc. we can see that the steady-state error of the control system becomes zero, but when the integration factor fl is small, the system's response is slow, and when it is too large, there is a high overshoot and s
24、erious oscillation. therefore, we may want to introduce the derivative control law into the fuzzy controller to overcome the overshoot and instability. we propose a controller structure that simply connects the pd type and the pi type fuzzy controller together in parallel. we have the equivalent str
25、ucture of that by connecting a pi device with the basic fuzzy controller serially as shown in fig.6. where is the weight on pd type fuzzy controller and fi is that on pi type fuzzy controller, the larger a/fi means more emphasis on the derivative control and less emphasis on the integration control,
26、 and vice versa. it follows from (7) that the output of the fuzzy controller is (3)3. the parameter adaptive method thus the fuzzy controller behaves like a time-varying pid controller, its equivalent proportional control, integral control and derivative control components are respectively. we call
27、this new controller structure a pid type fuzzy controller (pid fc). figs. 7 and 8 are the simulation results of the system's step response of such control system. the influence of and fl to the system performance is illustrated. when > 0 and/3 = 0, meaning that the fuzzy controller behaves li
28、ke pd fc, there exist a steady-state error. when = 0 and fl > 0, meaning that the fuzzy controller behaves like a pi fc, the steady-state error of the system is eliminated but there is a large overshoot and serious oscillation.when > 0 and 13 > 0 the fuzzy controller becomes a pid fc, the o
29、vershoot is substantially reduced. it is possible to get a comparatively good performance by carefully choosing the value of and. 4. conclusions we have studied the input-output behavior of the product-sum crisp type fuzzy controller, revealing that this type of fuzzy controller behaves approximatel
30、y like a parameter time-varying pd controller. therefore, the analysis and designing of a fuzzy control system can take advantage of the conventional pid control theory. according to the coventional pid control theory, we have been able to propose some improvement methods for the crisp type fuzzy co
31、ntroller. it has been illustrated that the pd type fuzzy controller yields a steady-state error for the type system, the pi type fuzzy controller can eliminate the steady-state error. we proposed a controller structure, that combines the features of both pd type and pi type fuzzy controller, obtaini
32、ng a pid type fuzzy controller which allows the control system to have a fast rise and a small overshoot as well as a short settling time. to improve further the performance of the proposed pid type fuzzy controller, the authors designed a parameter adaptive fuzzy controller. the pid type fuzzy cont
33、roller can be decomposed into the equivalent proportional control, integral control and the derivative control components. the proposed parameter adaptive fuzzy controller decreases the equivalent integral control component of the fuzzy controller gradually with the system response process time, so
34、as to increase the damping of the system when the system is about to settle down, meanwhile keeps the proportional control component unchanged so as to guarantee quick reaction against the system's error. with the parameter adaptive fuzzy controller, the oscillation of the system is strongly res
35、trained and the settling time is shortened considerably. we have presented the simulation results to demonstrate the fine performance of the proposed pid type fuzzy controller and the parameter adaptive fuzzy controller structure. part 2 application of self adaptation fuzzy-pid control for main stea
36、m temperature control system in power stationzhi-bin liabstract: in light of the large delay, strong inertia, and uncertainty characteristics of main steam temperature process, a self adaptation fuzzy-pid serial control system is presented, which not only contains the anti-disturbance performance of
37、 serial control, but also combines the good dynamic performance of fuzzy control. the simulation results show that this control system has more quickly response, better precision and stronger anti-disturbance abilitykeywords:main steam temperature;self adaptation;fuzzy control;serial control1. intro
38、ductionthe boiler superheaters of modem thermal power station run under the condition of high temperature and high pressure, and the superheaters temperature is highest in the steam channelsso it has important effect to the running of the whole thermal power stationif the temperature is too high, it
39、 will be probably burnt out. if the temperature is too low ,the efficiency will be reduced so the main steam temperature mast be strictly controlled near the given valuefig l shows the boiler main steam temperature system structure.fig.1 boiler main steam temperature systemit can be concluded from f
40、ig l that a good main steam temperature control system not only has adequately quickly response to flue disturbance and load fluctuation, but also has strong control ability to desuperheating water disturbance. the general control scheme is serial pid control or double loop control system with deriv
41、ative. but when the work condition and external disturbance change large, the performance will become instable. this paper presents a self adaptation fuzzy-pid serial control system. which not only contains the anti-disturbance performance of serial control, but also combines the good dynamic charac
42、ter and quickly response of fuzzy control1. design of control system the general regulation adopts serial pid control system with load feed forwardwhich assures that the main steam temperature is near the given value 540in most conditionif parameter of pid control changeless and the work condition a
43、nd external disturbance change large, the performance will become in stablethe fuzzy control is fit for controlling non-linear and uncertain process. the general fuzzy controller takes error e and error change ratio ec as input variablesactually it is a non-linear pd controller, so it has the good d
44、ynamic performancebut the steady error is still in existence. in linear system theory, integral can eliminate the steady error. so if fuzzy control is combined with pi control, not only contains the anti-disturbance performance of serial control, but also has the good dynamic performance and quickly
45、 response.in order to improve fuzzy control self adaptation ability, proflong sheng-zhao and wang pei-zhuang take the located in bringing forward a new idea which can modify the control regulation onlinethis regulation is: this control regulation depends on only one parameter.onceis fixedthe weight
46、of e and ec will be fixed and the self adaptation ability will be very smallit was improved by prof. li dong-hui and the new regulation is as follow; because it is very difficult to find a self of optimum parameter, a new method is presented by profzhou xian-lan, the regulation is as follow: but thi
47、s algorithm still can not eliminate the steady errorthis paper combines this algorithm with pi control,the performance is improved2. simulation of control system3.1 dynamic character of controlled object papers should be limited to 6 pages papers longer than 6 pages will be subject to extra fees bas
48、ed on their lengthfig .2 main steam temperature control system structurefig 2 shows the main steam temperature control system structure,are main controller and auxiliary controller,are characters of the leading and inertia sections,are measure unit.3.2 simulation of the general serial pid control sy
49、stemthe simulation of the general serial pid control system is operated by matlab, the simulation modal is as fig.3.setp1 and setp2 are the given value disturbance and superheating water disturb & rice .pid controller1 and pid controller2 are main controller and auxiliary controllerthe parameter
50、 value which comes from references is as follow:fig.3. the general pid control system simulation modal3.3 simulation of self adaptation fuzzy-pid control system spacingthe simulation modal is as fig 4.auxiliary controller is:.main controller is fuzzy-pi structure, and the pi controller is:fuzzy cont
51、roller is realized by s-function, and the code is as fig.5.fig.4. the fuzzy pid control system simulation modalfig 5 the s-function code of fuzzy control3.4 comparison of the simulationgiven the same given value disturbance and the superheating water disturbance,we compare the response of fuzzy-pid
52、control system with pid serial control system. the simulation results are as fig.6-7. from fig6-7,we can conclude that the self adaptation fuzzy-pid control system has the more quickly response, smaller excess and stronger anti-disturbance4. conclusion(1)because it combines the advantage of pid cont
53、roller and fuzzy controller, the self adaptation fuzzy-pid control system has better performance than the general pid serial control system. (2)the parameter can self adjust according to the error e value. so this kind of controller can harmonize quickly response with system stabilitypart 3 neuro-fu
54、zzy generalized predictive control of boiler steam temperature xiangjie liu, jizhen liu, ping guan abstract: power plants are nonlinear and uncertain complex systems. reliable control of superheated steam temperature is necessary to ensure high efficiency and high load-following capability in the op
55、eration of modern power plant. a nonlinear generalized predictive controller based on neuro-fuzzy network (nfgpc) is proposed in this paper. the proposed nonlinear controller is applied to control the superheated steam temperature of a 200mw power plant. from the experiments on the plant and the sim
56、ulation of the plant, much better performance than the traditional controller is obtained. keywords: neuro-fuzzy networks; generalized predictive control; superheated steam temperature1. introduction continuous process in power plant and power station are complex systems characterized by nonlinearit
57、y, uncertainty and load disturbance. the superheater is an important part of the steam generation process in the boiler-turbine system, where steam is superheated before entering the turbine that drives the generator. controlling superheated steam temperature is not only technically challenging, but
58、 also economically important. from fig.1,the steam generated from the boiler drum passes through the low-temperature superheater before it enters the radiant-type platen superheater. water is sprayed onto the steam to control the superheated steam temperature in both the low and high temperature superheaters. proper control of the superheated steam temperature is extremely important to ensure the overall efficiency and safety of the power plant. it is undesirable
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