CN107168042A - A kind of IMC methods of two-output impulse generator NDCS random delay - Google Patents

Abstract

The IMC methods of two-output impulse generator NDCS random delay, belong to the multiple-input and multiple-output NDCS systems technologies field of limited bandwidth resources.For affecting one another and coupling between a kind of two-output impulse generator signal, need the TITO NDCS by decoupling processing, due to network delay produced in network data among the nodes transmitting procedure, not only influence the stability of respective close loop control circuit, but also the stability of whole system will be influenceed, even result in the problem of TITO NDCS lose stable, propose with the live network data transmission procedure between all nodes in TITO NDCS, instead of the method for network delay compensation model therebetween, and IMC is implemented to its loop, the measurement to network delay between node can be exempted, estimation is recognized, reduce the requirement of clock signal synchronization, reduce influence of the network random delay to TITO NDCS stability, the control performance quality of improvement system.

Description

A kind of IMC methods of two-output impulse generator NDCS random delay

Technical field

When a kind of two-output impulse generator NDCS (Networked decoupling control systems, NDCS) is random IMC (Internal Model Control, the IMC) method prolonged, is related to automatic control technology, the network communications technology and computer Technology crossing domain, more particularly to limited bandwidth resources multiple-input and multiple-output network decoupling and controlling system technical field.

Background technology

With the development of network service, computer and control technology, and production process control increasingly maximization, wide area The development of change, complication and networking, increasing application of net is in control system.Network control system (Networked control systems, NCS) refers to network real-time closed-loop feedback control system, NCS typical case's knot Structure is as shown in Figure 1.

Compared with traditional point-to-point direct control system, NCS maximum feature be sensor in system, controller and Actuator is not direct point-to-point connection, but exchanges data and control information by public network, has broken traditional control Limitation of the system processed on locus, can be achieved system control and the remote monitoring under complex environment, reduces the wiring of system Complexity and Operations Management cost, improve the information integration of control system, the flexibility and reliability of strengthening system.

NCS by its interactivity it is strong, connect up less, extension and easy to maintenance and the advantages of resource-sharing can be realized, extensively It is general to be applied to the fields such as national defence, Aero-Space, device fabrication, intelligent transportation, process control and economic management.

But, while adding communication network in feedback control loop, also increase control system analysis and design Complexity.Due to the presence of the phenomenons such as network delay, data packetloss and network congestion so that NCS faces many new challenges. Especially it is uncertain of the presence of network delay, it is possible to decrease NCS control quality, or even makes system loss of stability, can when serious System can be caused to break down.

At present, research both at home and abroad for NCS, primarily directed to single-input single-output (Single-input and Single-output, SISO) network control system, constant, uncertain or random in network delay respectively, network delay is less than One sampling period or more than one sampling period, single bag transmission or many bag transmission, when whetheing there is data-bag lost, to it Carry out mathematical modeling or stability analysis and controlling.But, in actual industrial process, generally existing comprises at least two Multiple-input and multiple-output (the Multiple- that input is constituted with two outputs (Two-input and two-output, TITO) Input and multiple-output, MIMO) network control system research it is then relatively fewer, in particular for input with Between output signal, there is coupling needs the multiple-input and multiple-output network decoupling and controlling system by decoupling processing The achievement in research of (Networked decoupling control systems, NDCS) delay compensation is then relatively less.

MIMO-NDCS typical structure is as shown in Figure 2.

Compared with SISO-NCS, MIMO-NDCS has the characteristics that：

(1) affected one another between input signal and output signal and there is coupling

In it there is the MIMO-NCS of coupling, the change of an input signal will become multiple output signals Change, and each output signal is also not only influenceed by an input signal.Even if by meticulous between input and output signal Also exist and influence each other unavoidably between selection pairing, each control loop, thus to make output signal independently tracked respective defeated Enter signal to have any problem.Decoupler in MIMO-NDCS, for releasing or reducing the coupling between MIMO signal Effect.

(2) internal structure is more more complex than SISO-NCS

(3) controlled device there may be uncertain factor

In MIMO-NDCS, the parameter being related to is more, and the contact between each control loop is more, and parameter variations are to overall control The influence of effect processed can become very complicated.

(4) control unit fails

In MIMO-NDCS, including at least there is two or more close loop control circuits, including at least have two or More than two sensors and actuator.The failure of each element may influence the performance of whole control system, when serious Control system can be made unstable, or even caused a serious accident.

Due to MIMO-NDCS above-mentioned particularity so that be mostly based on the method that SISO-NCS is designed and controlled, MIMO-NDCS control performance and the requirement of control quality can not have been met, prevent its from or be not directly applicable MIMO- In NDCS design and analysis, control and design to MIMO-NDCS bring certain difficulty.

For MIMO-NDCS, network delay compensation is essentially consisted in the difficult point controlled：

(1) due to network delay and network topology structure, communication protocol, network load, the network bandwidth and data package size It is relevant etc. factor, controlled to more than several or even the dozens of sampling period random network time delay, to set up each in MIMO-NDCS The mathematical modeling that the network delay in loop processed is accurately predicted, estimates or recognized, is nearly impossible at present.

(2) occur in MIMO-NDCS, when previous node is to network during latter node-node transmission network data Prolong, no matter using which kind of prediction or method of estimation in previous node, be impossible to know the net produced thereafter in advance in advance Network time delay exact value.Time delay cause systematic function decline in addition cause system unstable, while also to control system analysis with Design brings difficulty.

(3) to meet in MIMO-NDCS, all node clock signal Complete Synchronizations in different distributions place are unrealistic 's.

(4) due in MIMO-NCS, being affected one another between input and output, and there is coupling, its MIMO-NDCS's Internal structure is more complicated than MIMO-NCS and SISO-NCS, it is understood that there may be uncertain factor it is more, implement time delay benefit to it Repay more much more difficult than MIMO-NCS and SISO-NCS with control.

The content of the invention

The present invention relates to a kind of compensation of two-output impulse generator NDCS (TITO-NDCS) random delay in MIMO-NCS with Control, its TITO-NDCS typical structure is as shown in Figure 3.

For the close loop control circuit 1 in Fig. 3：

1) from input signal x₁(s) output signal y is arrived₁(s) closed loop transfer function, between is：

In formula：C₁(s) it is controller, G₁₁(s) it is controlled device；τ₁Represent control signal u₁(s) from C₁(s) controller The C1 nodes at place, the network delay that actuator DA1 nodes are undergone is decoupled through preceding be transferred to network path；τ₂Expression will be defeated Go out signal y₁(s) from sensor S1 nodes, through feedback network tunnel to C₁(s) the C1 nodes where controller are undergone Network delay.

2) the control signal u in the decoupling actuator DA2 nodes from close loop control circuit 2₂(s) intersection solution, is acted on Coupling passage P₁₂(s) unit and cross decoupling network transmission channelsUnit, its output signal y_p12(s) remake for closed loop control Loop 1 processed, from input signal u₂(s) output signal y is arrived₁(s) closed loop transfer function, is between：

3) the drive signal u of actuator DA2 nodes output is decoupled from close loop control circuit 2_2p(s) controlled device, is passed through Cross aisle transmission function G₁₂(s) the output signal y of close loop control circuit 1 is acted on₁(s), from input signal u_2p(s) to output Signal y₁(s) closed loop transfer function, is between：

Above-mentioned closed loop transfer function, equation (1) and the denominator of (3)In, contain network it is random when Prolong τ₁And τ₂Exponential termWithThe presence of time delay will deteriorate the performance quality of control system, and the system of even resulting in loses surely It is qualitative.

For the close loop control circuit 2 in Fig. 3：

1) from input signal x₂(s) output signal y is arrived₂(s) closed loop transfer function, between is：

In formula：C₂(s) it is controller, G₂₂(s) it is controlled device；τ₃Represent control signal u₂(s) from C₂(s) controller The C2 nodes at place, the network delay that actuator DA2 nodes are undergone is decoupled through preceding be transferred to network path；τ₄Expression will be defeated Go out signal y₂(s) from sensor S2 nodes, through feedback network tunnel to C₂(s) the C2 nodes where controller are undergone Network delay.

2) the control signal u in the decoupling actuator DA1 nodes from close loop control circuit 1₁(s) intersection solution, is acted on Coupling passage P₂₁(s) unit and cross decoupling network transmission channelsUnit, its output signal y_p21(s) remake for closed loop control Loop 2 processed, from input signal u₁(s) output signal y is arrived₂(s) closed loop transfer function, is between：

3) the drive signal u of actuator DA1 nodes output is decoupled from close loop control circuit 1_1p(s) controlled device, is passed through Cross aisle transmission function G₂₁(s) the output signal y of close loop control circuit 2 is acted on₂(s), from input signal u_1p(s) to output Signal y₂(s) closed loop transfer function, is between：

Above-mentioned closed loop transfer function, equation (4) and the denominator of (6)In, contain network it is random when Prolong τ₃And τ₄Exponential termWithThe presence of time delay will deteriorate the performance quality of control system, and the system of even resulting in loses surely It is qualitative.

Goal of the invention：

For Fig. 3 TITO-NDCS, in the transmission function equation (1) of its close loop control circuit 1 and the denominator of (3), wrap Network random delay τ is contained₁And τ₂Exponential termWithAnd the transmission function equation (4) of close loop control circuit 2 and (6) Denominator in, contain network random delay τ₃And τ₄Exponential termWith

Due to the output signal y of close loop control circuit 1₁(s) not only by its input signal x₁(s) influence, at the same also by To the input signal x of close loop control circuit 2₂(s) influence；At the same time, the output signal y of close loop control circuit 2₂(s) not only By its input signal x₂(s) influence, while also by the input signal x of close loop control circuit 1₁(s) influence；During network The presence prolonged can reduce the control performance quality of respective close loop control circuit and influence the stability of respective close loop control circuit, together When will also decrease the control performance quality of whole system and influence the stability of whole system, whole system will be caused to lose when serious Go stability.

Therefore, for the close loop control circuit 1 in Fig. 3 and control loop 2：The present invention proposes a kind of IMC methods, constitutes two The compensation of close loop control circuit network delay and IMC, for exempting in each close loop control circuit, between node during random network Measurement, estimation or the identification prolonged, and then reduce network delay τ₁And τ₂, and τ₃And τ₄To respective close loop control circuit and right The influence of whole control system control performance quality and the stability of a system；The dynamic property quality of improvement system, is realized to TITO- Being segmented of NDCS random network time delays, in real time, online and dynamic predictive compensation and IMC.

Using method：

For the close loop control circuit 1 in Fig. 3：

The first step：In controller C1 nodes, an internal mode controller C is built_1IMC(s) substitution controller C₁(s)；In order to When realization meets predictive compensation condition, the exponential term of network delay is no longer included in the closed loop transform function of close loop control circuit 1, To realize to network delay τ₁And τ₂Compensation and control, use with control signal u₁(s) as input signal, controlled device is pre- Estimate model G_11m(s) as controlled process, control passes through network transfer delay prediction model with process dataAndEnclose Around internal mode controller C_1IMC(s) a positive feedback Prediction Control loop is constructed；The structure for implementing this step is as shown in Figure 4；

Second step：For in actual TITO-NDCS, it is difficult to the problem of obtaining network delay exact value, to realize in Fig. 4 Compensation and IMC to network delay, in addition to the condition that controlled device prediction model to be met is equal to its true model, it is necessary to Meet random network Time-delay Prediction modelAndTo be equal to its true modelAndCondition.Therefore, from biography Sensor S1 nodes are between controller C1 nodes, and from controller C1 nodes to decoupling actuator DA1 nodes, using true Real network data transmission processAndInstead of network delay predict-compensate model therebetweenAndThus nothing Whether it is equal to its true model by the prediction model of controlled device, when can be realized from system architecture not comprising network therebetween The predict-compensate model prolonged, so as to exempt in close loop control circuit 1, random network delay, τ between node₁And τ₂Measurement, estimate Meter is recognized；The network delay compensation for implementing the inventive method is as shown in Figure 5 with IMC structures；

For the close loop control circuit 2 in Fig. 3：

The first step：In controller C2 nodes, an internal mode controller C is built_2IMC(s) substitution controller C₂(s)；In order to When realization meets predictive compensation condition, the exponential term of network delay is no longer included in the closed loop transform function of close loop control circuit 2, To realize to network delay τ₃And τ₄Compensation and control, use with control signal u₂(s) as input signal, controlled device is pre- Estimate model G_22m(s) as controlled process, control passes through network transfer delay prediction model with process dataAndEnclose Around internal mode controller C_2IMC(s) a positive feedback Prediction Control loop is constructed；The structure for implementing this step is as shown in Figure 4；

Second step：For in actual TITO-NDCS, it is difficult to the problem of obtaining network delay exact value, to realize in Fig. 4 Compensation and IMC to network delay, in addition to the condition that controlled device prediction model to be met is equal to its true model, it is necessary to Meet random network Time-delay Prediction modelAndTo be equal to its true modelAndCondition.Therefore, from biography Sensor S2 nodes are between controller C2 nodes, and from controller C2 nodes to decoupling actuator DA2 nodes, using true Real network data transmission processAndInstead of network delay predict-compensate model therebetweenAndThus nothing Whether it is equal to its true model by the prediction model of controlled device, when can be realized from system architecture not comprising network therebetween The predict-compensate model prolonged, so as to exempt in close loop control circuit 2, random network delay, τ between node₃And τ₄Measurement, estimate Meter is recognized；The network delay compensation for implementing the inventive method is as shown in Figure 5 with IMC structures.

For the close loop control circuit 1 in Fig. 5：

1) from input signal x₁(s) output signal y is arrived₁(s) closed loop transfer function, between is：

In formula：G_11m(s) it is controlled device G₁₁(s) prediction model, C_1IMC(s) it is internal mode controller.

2) the control signal u in the decoupling actuator DA2 nodes from close loop control circuit 2₂(s) intersection solution, is acted on Coupling passage P₁₂(s) unit and cross decoupling network transmission channelsUnit, its output signal y_p12(s) remake for closed loop control Loop 1 processed, from input signal u₂(s) output signal y is arrived₁(s) closed loop transfer function, is between：

3) the drive signal u of actuator DA2 nodes output is decoupled from close loop control circuit 2_2p(s) controlled device, is passed through Cross aisle transmission function G₁₂(s) the output signal y of close loop control circuit 1 is acted on₁(s), from input signal u_2p(s) to output Signal y₁(s) closed loop transfer function, is between：

When controlled device prediction model is equal to its true model, that is, work as G_11m(s)=G₁₁(s) when, close loop control circuit 1 Closed loop transfer function, denominator byIt is turned into 1；Now, close loop control circuit 1 is equivalent to one The network delay τ of the influence stability of a system is no longer included in individual open-loop control system, the denominator of closed loop transfer function,₁And τ₂ Exponential termWithThe stability of system only with controlled device and internal mode controller and cross decoupling channel transfer function The stability of itself is relevant；Using the inventive method, it is possible to decrease influence of the network delay to the stability of a system, improve the dynamic of system State control performance quality, realizes the dynamic compensation to random network time delay and IMC.

For the close loop control circuit 2 in Fig. 5：

1) from input signal x₂(s) output signal y is arrived₂(s) closed loop transfer function, between is：

In formula：G_22m(s) it is controlled device G₂₂(s) prediction model, C_2IMC(s) it is internal mode controller.

2) the control signal u in the decoupling actuator DA1 nodes from close loop control circuit 1₁(s) intersection solution, is acted on Coupling passage P₂₁(s) unit and cross decoupling network transmission channelsUnit, its output signal y_p21(s) remake for closed-loop control Loop 2, from input signal u₁(s) output signal y is arrived₂(s) closed loop transfer function, is between：

3) the drive signal u of actuator DA1 nodes output is decoupled from close loop control circuit 1_1p(s) controlled device, is passed through Cross aisle transmission function G₂₁(s) the output signal y of close loop control circuit 2 is acted on₂(s), from input signal u_1p(s) to output Signal y₂(s) closed loop transfer function, is between：

When controlled device prediction model is equal to its true model, that is, work as G_22m(s)=G₂₂(s) when, close loop control circuit 2 Closed loop transfer function, denominator byIt is turned into 1；Now, close loop control circuit 2 equivalent to The network delay τ of the influence stability of a system is no longer included in one open-loop control system, the denominator of closed loop transfer function,₃With τ₄Exponential termWithThe stability of system only transmits letter with controlled device and internal mode controller and cross decoupling passage The stability of number itself is relevant；Using the inventive method, it is possible to decrease influence of the network delay to the stability of a system, improve system Dynamic control performance quality, realizes the dynamic compensation to random network time delay and IMC.

In close loop control circuit 1 and loop 2, internal mode controller C_1IMCAnd C (s)_2IMC(s) design and selection：

Design internal mode controller and typically use pole-zero cancellation method, i.e. two step design methods：The first step is that design one takes it Feedforward controller C is used as the inversion model of plant model₁₁And C (s)₂₂(s)；Second step is added in feedforward controller The feedforward filter f of certain order₁And f (s)₂(s) a complete internal mode controller C, is constituted_1IMCAnd C (s)_2IMC(s)。

1) feedforward controller C₁₁And C (s)₂₂(s)

Error, the interference of system when first ignoring controlled device and plant model Incomplete matching and it is other it is various about The factors such as beam condition, in selection close loop control circuit 1 and loop 2, controlled device prediction model is equal to its true model, i.e.,：G_11m (s)=G₁₁(s), G_22m(s)=G₂₂(s)。

Now, controlled device prediction model can be divided into according to the poles and zeros assignment situation of controlled device：G_11m(s)= G_11m+(s)G_11m-And G (s)_22m(s)=G_22m+(s)G_22m-(s), wherein：G_11m+And G (s)_22m+(s) it is respectively that controlled device is estimated Model G_11mAnd G (s)_22m(s) the irreversible part comprising pure lag system and s RHP zero pole points in；G_11m-And G (s)_22m- (s) it is respectively the reversible part of minimum phase in controlled device prediction model.

Under normal circumstances, the feedforward controller C in close loop control circuit 1 and loop 2₁₁And C (s)₂₂(s) it can be chosen for respectively：With

2) feedforward filter f₁And f (s)₂(s)

The thing of feedforward controller can be influenceed due to the pure lag system in controlled device and positioned at the zero pole point of s RHPs Reason is realisation, thus has only taken in the design process of feedforward controller the reversible part G of controlled device minimum phase_11m-(s) And G_22m-(s) it, have ignored G_11m+And G (s)_22m+(s)；Due to possible incomplete between controlled device and controlled device prediction model Match and there is error, interference signal is there is likely to be in system, these factors are likely to make system lose stabilization.Therefore, The feedforward filter of certain order is added in feedforward controller, for reducing influence of the factors above to the stability of a system, is carried The robustness of high system.

Generally the feedforward filter f of close loop control circuit 1₁(s), and control loop 2 feedforward filter f₂(s), divide Fairly simple n is not chosen for₁And n₂Rank wave filterWithWherein：λ₁And λ₂For feedforward Filter time constant；n₁And n₂For the order of feedforward filter, and n₁=n_1a-n_1bAnd n₂=n_2a-n_2b；n_1aAnd n_2aRespectively Controlled device G₁₁And G (s)₂₂(s) order of denominator；n_1bAnd n_2bRespectively controlled device G₁₁And G (s)₂₂(s) order of molecule, Usual n₁＞ 0 and n₂＞ 0.

3) internal mode controller C_1IMCAnd C (s)_2IMC(s)

Close loop control circuit 1 and the internal mode controller C in loop 2_1IMCAnd C (s)_2IMC(s) it can be chosen for respectively:

With

It can be seen that from equation (13) and (14)：The internal mode controller C of one degree of freedom_1IMCAnd C (s)_2IMC(s) in, all Only one of which customized parameter λ₁And λ₂；Due to λ₁And λ₂The change of parameter and the tracking performance of system and antijamming capability have Direct relation, therefore is adjusting the customized parameter λ of wave filter₁And λ₂When, the tracing property generally required in system is done with anti- Ability is disturbed to trade off between the two.

The scope of application of the present invention：

It is equal to suitable for controlled device prediction model between its true model, or prediction model and its true model and has one During fixed deviation, a kind of two-output impulse generator network decoupling and controlling system (TITO-NDCS) the random network time delay constituted Compensation and IMC；Its Research Thinking and method, can equally be well applied to controlled device prediction model equal to its true model, or estimate When there is certain deviation between model and its true model, the multiple-input and multiple-output network decoupling and controlling system constituted (MIMO-NDCS) compensation of random network time delay and IMC.

It is a feature of the present invention that this method comprises the following steps：

For close loop control circuit 1：

(1) is h when the sensor S1 nodes cycle₁Sampled signal triggering when, employing mode A is operated；

(2) is when controller C1 nodes are by feedback signal y_1b(s) when triggering, employing mode B is operated；

(3) is when decoupling actuator DA1 nodes are by IMC signals u₁(s) or by from cross decoupling network transmission channelsThe output signal y of unit_p12(s) when triggering, employing mode C is operated；

For close loop control circuit 2：

(4) is h when the sensor S2 nodes cycle₂Sampled signal triggering when, employing mode D is operated；

(5) is when controller C2 nodes are by feedback signal y_2b(s) when triggering, employing mode E is operated；

(6) is when decoupling actuator DA2 nodes are by IMC signals u₂(s) or by from cross decoupling network transmission channelsThe output signal y of unit_p21(s) when triggering, employing mode F is operated；

The step of mode A, includes：

A1：Sensor S1 nodes work in time type of drive, and its trigger signal is cycle h₁Sampled signal；

A2：After sensor S1 nodes are triggered, to controlled device G₁₁(s) output signal y₁₁(s) intersect with controlled device Channel transfer function G₁₂(s) output signal y₁₂(s), and decoupling actuator DA1 nodes output signal y_11mb(s) adopted Sample, and calculate the system output signal y of close loop control circuit 1₁(s) with feedback signal y_1b, and y (s)₁(s)=y₁₁(s)+y₁₂ And y (s)_1b(s)=y₁(s)-y_11mb(s)；

A3：By feedback signal y_1b(s), by the feedback network path of close loop control circuit 1 to controller C1 node-node transmissions, Feedback signal y_1b(s) will experience network transfer delay τ₂Afterwards, controller C1 nodes are got to；

The step of mode B, includes：

B1：Controller C1 nodes work in event driven manner, by feedback signal y_1b(s) triggered；

B2：In controller C1 nodes, by the system Setting signal x of close loop control circuit 1₁(s) feedback signal y, is subtracted_1b (s) deviation signal e, is obtained₁(s), i.e. e₁(s)=x₁(s)-y_1b(s)；

B3：To e₁(s) IMC algorithms C is implemented_1IMC(s) IMC signals u, is obtained₁(s)；

B4：By IMC signals u₁(s) the feedforward network path of close loop control circuit 1 is passed throughUnit to decoupling actuator DA1 Node-node transmission, IMC signals u₁(s) will experience network transfer delay τ₁Afterwards, get to decouple actuator DA1 nodes；

The step of mode C, includes：

C1：Decoupling actuator DA1 nodes work in event driven manner, by IMC signals u₁(s) or Self-crossover solution is carried out Coupling network transmission channelsThe output signal y of unit_p12(s) triggered；

C2：By IMC signals u₁(s) controlled device prediction model G is acted on_11m(s) its output valve y is obtained_11mb(s)；

C3：By IMC signals u₁(s) cross decoupling passage P is acted on₂₁(s) unit obtains its output signal y_p21(s)；

C4：By signal y_p21(s) cross decoupling network transmission channels are passed throughUnit, to the decoupling of close loop control circuit 2 Actuator DA2 node-node transmissions；Signal y_p21(s) will experience network transfer delay τ₂₁Afterwards, get to decouple actuator DA2 nodes；

C5：By IMC signals u₁(s) the IMC signals u of actuator DA2 nodes is decoupled with coming from close loop control circuit 2₂(s) Pass through cross decoupling passage P₁₂(s) unit and cross decoupling network transmission channelsThe output signal y of unit_p12(s) subtract each other To signal u_1p(s), i.e. u_1p(s)=u₁(s)-y_p12(s)；

C6：By signal u_1p(s) controlled device G is acted on₁₁(s) its output valve y is obtained₁₁(s)；By signal u_1p(s) act on Controlled device cross aisle transmission function G₂₁(s) its output valve y is obtained₂₁(s)；So as to realize to controlled device G₁₁And G (s)₂₁ (s) decoupling and control, while realizing to network random delay τ₁And τ₂Compensation and IMC；

The step of mode D, includes：

D1：Sensor S2 nodes work in time type of drive, and its trigger signal is cycle h₂Sampled signal；

D2：After sensor S2 nodes are triggered, to controlled device G₂₂(s) output signal y₂₂(s) intersect with controlled device Channel transfer function G₂₁(s) output signal y₂₁(s), and decoupling actuator DA2 nodes output signal y_22mb(s) adopted Sample, and calculate the system output signal y of close loop control circuit 2₂(s) with feedback signal y_2b, and y (s)₂(s)=y₂₂(s)+y₂₁ And y (s)_2b(s)=y₂(s)-y_22mb(s)；

D3：By feedback signal y_2b(s), by the feedback network path of close loop control circuit 2 to controller C2 node-node transmissions, Feedback signal y_2b(s) will experience network transfer delay τ₄Afterwards, controller C2 nodes are got to；

The step of mode E, includes：

E1：Controller C2 nodes work in event driven manner, by feedback signal y_2b(s) triggered；

E2：In controller C2 nodes, by the system Setting signal x of close loop control circuit 2₂(s) feedback signal y, is subtracted_2b (s) deviation signal e, is obtained₂(s), i.e. e₂(s)=x₂(s)-y_2b(s)；

E3：To e₂(s) IMC algorithms C is implemented_2IMC(s) IMC signals u, is obtained₂(s)；

E4：By IMC signals u₂(s) the feedforward network path of close loop control circuit 2 is passed throughUnit to decoupling actuator DA2 node-node transmissions, IMC signals u₂(s) will experience network transfer delay τ₃Afterwards, get to decouple actuator DA2 nodes；

The step of mode F, includes：

F1：Decoupling actuator DA2 nodes work in event driven manner, by IMC signals u₂(s) or Self-crossover solution is carried out Coupling network transmission channelsThe output signal y of unit_p21(s) triggered；

F2：By IMC signals u₂(s) controlled device prediction model G is acted on_22m(s) its output valve y is obtained_22mb(s)；

F3：By IMC signals u₂(s) cross decoupling passage P is acted on₁₂(s) unit obtains its output signal y_p12(s)；

F4：By signal y_p12(s) cross decoupling network transmission channels are passed throughUnit, to the decoupling of close loop control circuit 1 Actuator DA1 node-node transmissions；Signal y_p12(s) will experience network transfer delay τ₁₂Afterwards, get to decouple actuator DA1 nodes；

F5：By IMC signals u₂(s) the IMC signals u of actuator DA1 nodes is decoupled with coming from close loop control circuit 1₁(s) Pass through cross decoupling passage P₂₁(s) unit and cross decoupling network transmission channelsThe output signal y of unit_p21(s) subtract each other To signal u_2p(s), i.e. u_2p(s)=u₂(s)-y_p21(s)；

F6：By signal u_2p(s) controlled device G is acted on₂₂(s) its output valve y is obtained₁₁(s)；By signal u_2p(s) act on Controlled device cross aisle transmission function G₁₂(s) its output valve y is obtained₁₂(s)；So as to realize to controlled device G₂₂And G (s)₁₂ (s) decoupling and control, while realizing to network random delay τ₃And τ₄Compensation and IMC.

The present invention has following features：

1st, due to from exempting in structure in TITO-NDCS, the measurement of random network time delay, observation, estimation or recognize, together When can also exempt the synchronous requirement of node clock signal, time delay can be avoided to estimate the inaccurate evaluated error caused of model, it is to avoid To expending the waste of node storage resources needed for time-delay identification, while can also avoid due to " sky sampling " or " many that time delay is caused The compensation error that sampling " is brought.

2nd, it is unrelated with the selection of specific network communication protocol due to from TITO-NDCS structures, realizing, thus be both applicable In the TITO-NDCS using wired network protocol, also suitable for the TITO-NDCS using wireless network protocol；It is not only suitable for really Qualitative procotol, also suitable for the procotol of uncertainty；The TITO-NDCS of heterogeneous network composition is not only suitable for, simultaneously Also it is applied to the TITO-NDCS that heterogeneous network is constituted.

3rd, the control loop 1 and control loop 2 in TITO-NDCS：Its internal mode controller is respectively C_1IMCAnd C (s)_2IMC (s)；The equal only one of which of adjustable parameter in its loop, respectively λ₁And λ₂Parameter, the regulation and selection of its parameter is simple, and physics Meaning is clear and definite；It can not only improve stability, tracking performance and the interference free performance of system using IMC, but also can realize pair The compensation of random network time delay and IMC；

4th, because the present invention uses compensation and control method that " software " changes TITO-NDCS structures, thus at it Any hardware device need not be further added by implementation process, the software resource carried using existing TITO-NDCS intelligent nodes, it is sufficient to Its compensation and control function are realized, hardware investment can be saved and be easy to be extended and applied.

Brief description of the drawings

Fig. 1：NCS typical structure

Fig. 1 is by sensor S nodes, controller C nodes, actuator A nodes, controlled device, feedforward network tunnel list MemberAnd feedback network tunnel unitConstituted.

In Fig. 1：X (s) represents system input signal；Y (s) represents system output signal；C (s) represents controller；U (s) tables Show control signal；τ_caRepresent the feedforward network for being undergone control signal u (s) from controller C nodes to actuator A node-node transmissions Tunnel time delay；τ_scRepresent the feedback net for being undergone the detection signal y (s) of sensor S nodes to controller C node-node transmissions Network tunnel time delay；G (s) represents controlled device transmission function.

Fig. 2：MIMO-NDCS typical structure

Fig. 2 is by r sensor S node, controller C nodes, m decoupling actuator DA node, controlled device G, m forward direction Network path propagation delay timeUnit, and r feedback network tunnel time delayUnit Constituted.

In Fig. 2：y_j(s) j-th of output signal of system is represented；u_i(s) i-th of control signal is represented；Representing will control Signal u_i(s) during the feedforward network tunnel undergone from controller C nodes to i-th of decoupling actuator DA node-node transmission Prolong；Represent the detection signal y of j-th of sensor S node_j(s) feedback network undergone to controller C node-node transmissions leads to Road propagation delay time；G represents controlled device transmission function.

Fig. 3：TITO-NDCS typical structure

Fig. 3 is made up of close loop control circuit 1 and 2, and its system includes sensor S1 and S2 node, controller C1 and C2 section Point, decouples actuator DA1 and DA2 node, controlled device transmission function G₁₁And G (s)₂₂(s) and controlled device cross aisle pass Delivery function G₂₁And G (s)₁₂(s), feedforward network tunnel unitWithAnd feedback network tunnel unit WithCross decoupling channel transfer function P₂₁And P (s)₁₂, and cross decoupling network path transmission unit (s)With Constituted.

In Fig. 3：x₁And x (s)₂(s) input signal of system is represented；y₁And y (s)₂(s) output signal of system is represented；C₁ And C (s)₂(s) controller of control loop 1 and 2 is represented；u₁And u (s)₂(s) control signal is represented；y_p21And y (s)_p12(s) represent Cross decoupling multi-channel output signal；u_1pAnd u (s)_2p(s) be decouple actuator DA1 and DA2 node output drive signal；τ₂₁With τ₁₂Represent cross decoupling channel transfer function P₂₁And P (s)₁₂(s) output signal y_p21And y (s)_p12(s) to decoupling actuator The network path propagation delay time that DA2 and DA1 node-node transmissions are undergone；τ₁And τ₃Represent control signal u₁And u (s)₂(s) from control The feedforward network tunnel time delay that device C1 and C2 nodes processed are undergone to decoupling actuator DA1 and DA2 node-node transmission；τ₂And τ₄ Represent the detection signal y of sensor S1 and S2 node₁And y (s)₂(s) feedback undergone to controller C1 and C2 node-node transmission Network path propagation delay time.

Fig. 4：A kind of TITO-NDCS delay compensations and control structure comprising prediction model

In Fig. 4：G_11m(s) it is controlled device G₁₁(s) prediction model；G_22m(s) it is controlled device G₂₂(s) estimate mould Type；AndIt is network transfer delayAndEstimate Time Delay Model；AndIt is network transfer delayAndEstimate Time Delay Model.

Fig. 5：A kind of IMC methods of two-output impulse generator NDCS random delay

Embodiment

The exemplary embodiment of the present invention will be described in detail by referring to accompanying drawing 5 below, makes the ordinary skill people of this area Member becomes apparent from the features described above and advantage of the present invention.

Specific implementation step is as described below：

For close loop control circuit 1：

The first step：Sensor S1 nodes work in time type of drive, are h when the sensor S1 nodes cycle₁Sampling , will be to controlled device G after signal triggering₁₁(s) output signal y₁₁(s) with controlled device cross aisle transmission function G₁₂(s) Output signal y₁₂(s), and decoupling actuator DA1 nodes output signal y_11mb(s) sampled, and calculate closed-loop control The system output signal y in loop 1₁(s) with feedback signal y_1b, and y (s)₁(s)=y₁₁(s)+y₁₂And y (s)_1b(s)=y₁(s)- y_11mb(s)；

Second step：Sensor S1 nodes are by feedback signal y_1b(s), by the feedback network path of close loop control circuit 1 to Controller C1 node-node transmissions, feedback signal y_1b(s) will experience network transfer delay τ₂Afterwards, controller C1 nodes are got to；

3rd step：Controller C1 nodes work in event driven manner, by feedback signal y_1b(s) after triggering, by closed loop The system Setting signal x of control loop 1₁(s) feedback signal y, is subtracted_1b(s) deviation signal e, is obtained₁(s), i.e. e₁(s)=x₁ (s)-y_1b(s)；To e₁(s) IMC algorithms C is implemented_1IMC(s) IMC signals u, is obtained₁(s)；

4th step：By IMC signals u₁(s) the feedforward network path of close loop control circuit 1 is passed throughUnit is performed to decoupling Device DA1 node-node transmissions, IMC signals u₁(s) will experience network transfer delay τ₁Afterwards, get to decouple actuator DA1 nodes；

5th step：Decoupling actuator DA1 nodes work in event driven manner, by IMC signals u₁(s) or selfing is carried out Pitch Decoupling network transmission channelThe output signal y of unit_p12(s) triggered；

6th step：After decoupling actuator DA1 nodes are triggered, by IMC signals u₁(s) act on controlled device and estimate mould Type G_11m(s) its output valve y is obtained_11mb(s)；

7th step：By IMC signals u₁(s) cross decoupling passage P is acted on₂₁(s) unit obtains its output signal y_p21(s)； By signal y_p21(s) cross decoupling network transmission channels are passed throughUnit, is saved to the decoupling actuator DA2 of close loop control circuit 2 Point transmission；Signal y_p21(s) will experience network transfer delay τ₂₁Afterwards, get to decouple actuator DA2 nodes；

8th step：By IMC signals u₁(s) the IMC signals u of actuator DA2 nodes is decoupled with coming from close loop control circuit 2₂ (s) cross decoupling passage P is passed through₁₂(s) unit and cross decoupling network transmission channelsThe output signal y of unit_p12(s) phase Subtract and obtain signal u_1p(s), i.e. u_1p(s)=u₁(s)-y_p12(s)；

9th step：By signal u_1p(s) controlled device G is acted on₁₁(s) its output valve y is obtained₁₁(s)；By signal u_1p(s) make For controlled device cross aisle transmission function G₂₁(s) its output valve y is obtained₂₁(s)；So as to realize to controlled device G₁₁(s) and G₂₁(s) decoupling and control, while realizing to random network delay, τ₁And τ₂Compensation and IMC；

Tenth step：Return to the first step；

For close loop control circuit 2：

The first step：Sensor S2 nodes work in time type of drive, are h when the sensor S2 nodes cycle₂Sampling , will be to controlled device G after signal triggering₂₂(s) output signal y₂₂(s) with controlled device cross aisle transmission function G₂₁(s) Output signal y₂₁(s), and decoupling actuator DA2 nodes output signal y_22mb(s) sampled, and calculate closed-loop control The system output signal y in loop 2₂(s) with feedback signal y_2b, and y (s)₂(s)=y₂₂(s)+y₂₁And y (s)_2b(s)=y₂(s)- y_22mb(s)；

Second step：Sensor S2 nodes are by feedback signal y_2b(s), by the feedback network path of close loop control circuit 2 to Controller C2 node-node transmissions, feedback signal y_2b(s) will experience network transfer delay τ₄Afterwards, controller C2 nodes are got to；

3rd step：Controller C2 nodes work in event driven manner, by feedback signal y_2b(s) after triggering, by closed loop The system Setting signal x of control loop 2₂(s) feedback signal y, is subtracted_2b(s) deviation signal e, is obtained₂(s), i.e. e₂(s)=x₂ (s)-y_2b(s)；To e₂(s) IMC algorithms C is implemented_2IMC(s) IMC signals u, is obtained₂(s)；

4th step：By IMC signals u₂(s) the feedforward network path of close loop control circuit 2 is passed throughUnit is performed to decoupling Device DA2 node-node transmissions, IMC signals u₂(s) will experience network transfer delay τ₃Afterwards, get to decouple actuator DA2 nodes；

5th step：Decoupling actuator DA2 nodes work in event driven manner, by IMC signals u₂(s) or selfing is carried out Pitch Decoupling network transmission channelThe output signal y of unit_p21(s) triggered；

6th step：After decoupling actuator DA2 nodes are triggered, by IMC signals u₂(s) act on controlled device and estimate mould Type G_22m(s) its output valve y is obtained_22mb(s)；

7th step：By IMC signals u₂(s) cross decoupling passage P is acted on₁₂(s) unit obtains its output signal y_p12(s)； By signal y_p12(s) cross decoupling network transmission channels are passed throughUnit, is saved to the decoupling actuator DA1 of close loop control circuit 1 Point transmission；Signal y_p12(s) will experience network transfer delay τ₁₂Afterwards, get to decouple actuator DA1 nodes；

8th step：By IMC signals u₂(s) the IMC signals u of actuator DA1 nodes is decoupled with coming from close loop control circuit 1₁ (s) cross decoupling passage P is passed through₂₁(s) unit and cross decoupling network transmission channelsThe output signal y of unit_p21(s) phase Subtract and obtain signal u_2p(s), i.e. u_2p(s)=u₂(s)-y_p21(s)；

9th step：By signal u_2p(s) controlled device G is acted on₂₂(s) its output valve y is obtained₂₂(s)；By signal u_2p(s) make For controlled device cross aisle transmission function G₁₂(s) its output valve y is obtained₁₂(s)；So as to realize to controlled device G₂₂(s) and G₁₂(s) decoupling and control, while realizing to random network delay, τ₃And τ₄Compensation and IMC；

Tenth step：Return to the first step；

It the foregoing is only presently preferred embodiments of the present invention and oneself, be not intended to limit the invention, all essences in the present invention God is with principle, and any modification, equivalent substitution and improvements made etc. should be included in the scope of the protection.

The content not being described in detail in this specification belongs to prior art known to professional and technical personnel in the field.

Claims (4)

1. a kind of IMC methods of two-output impulse generator NDCS random delay, it is characterised in that this method comprises the following steps：

For close loop control circuit 1：

(1) is h when the sensor S1 nodes cycle₁Sampled signal triggering when, employing mode A is operated；

(2) is when controller C1 nodes are by feedback signal y_1b(s) when triggering, employing mode B is operated；

(3) is when decoupling actuator DA1 nodes are by IMC signals u₁(s) or by from cross decoupling network transmission channelsUnit Output signal y_p12(s) when triggering, employing mode C is operated；

For close loop control circuit 2：

(4) is h when the sensor S2 nodes cycle₂Sampled signal triggering when, employing mode D is operated；

(5) is when controller C2 nodes are by feedback signal y_2b(s) when triggering, employing mode E is operated；

(6) is when decoupling actuator DA2 nodes are by IMC signals u₂(s) or by from cross decoupling network transmission channelsUnit Output signal y_p21(s) when triggering, employing mode F is operated；

The step of mode A, includes：

A1：Sensor S1 nodes work in time type of drive, and its trigger signal is cycle h₁Sampled signal；

A2：After sensor S1 nodes are triggered, to controlled device G₁₁(s) output signal y₁₁(s) with controlled device cross aisle Transmission function G₁₂(s) output signal y₁₂(s), and decoupling actuator DA1 nodes output signal y_11mb(s) sampled, And calculate the system output signal y of close loop control circuit 1₁(s) with feedback signal y_1b, and y (s)₁(s)=y₁₁(s)+y₁₂(s) And y_1b(s)=y₁(s)-y_11mb(s)；

A3：By feedback signal y_1b(s), fed back by the feedback network path of close loop control circuit 1 to controller C1 node-node transmissions Signal y_1b(s) will experience network transfer delay τ₂Afterwards, controller C1 nodes are got to；

The step of mode B, includes：

B1：Controller C1 nodes work in event driven manner, by feedback signal y_1b(s) triggered；

B2：In controller C1 nodes, by the system Setting signal x of close loop control circuit 1₁(s) feedback signal y, is subtracted_1b(s), Obtain deviation signal e₁(s), i.e. e₁(s)=x₁(s)-y_1b(s)；

B3：To e₁(s) IMC algorithms C is implemented_1IMC(s) IMC signals u, is obtained₁(s)；

B4：By IMC signals u₁(s) the feedforward network path of close loop control circuit 1 is passed throughUnit to decoupling actuator DA1 nodes Transmission, IMC signals u₁(s) will experience network transfer delay τ₁Afterwards, get to decouple actuator DA1 nodes；

The step of mode C, includes：

C1：Decoupling actuator DA1 nodes work in event driven manner, by IMC signals u₁(s) or by from cross decoupling net Network transmission channelThe output signal y of unit_p12(s) triggered；

C2：By IMC signals u₁(s) controlled device prediction model G is acted on_11m(s) its output valve y is obtained_11mb(s)；

C3：By IMC signals u₁(s) cross decoupling passage P is acted on₂₁(s) unit obtains its output signal y_p21(s)；

C4：By signal y_p21(s) cross decoupling network transmission channels are passed throughUnit, is performed to the decoupling of close loop control circuit 2 Device DA2 node-node transmissions；Signal y_p21(s) will experience network transfer delay τ₂₁Afterwards, get to decouple actuator DA2 nodes；

C5：By IMC signals u₁(s) the IMC signals u of actuator DA2 nodes is decoupled with coming from close loop control circuit 2₂(s) pass through Cross decoupling passage P₁₂(s) unit and cross decoupling network transmission channelsThe output signal y of unit_p12(s) subtract each other and obtain letter Number u_1p(s), i.e. u_1p(s)=u₁(s)-y_p12(s)；

C6：By signal u_1p(s) controlled device G is acted on₁₁(s) its output valve y is obtained₁₁(s)；By signal u_1p(s) act on controlled Object cross aisle transmission function G₂₁(s) its output valve y is obtained₂₁(s)；So as to realize to controlled device G₁₁And G (s)₂₁(s) Decoupling and control, while realizing to network random delay τ₁And τ₂Compensation and IMC；

The step of mode D, includes：

D1：Sensor S2 nodes work in time type of drive, and its trigger signal is cycle h₂Sampled signal；

D2：After sensor S2 nodes are triggered, to controlled device G₂₂(s) output signal y₂₂(s) with controlled device cross aisle Transmission function G₂₁(s) output signal y₂₁(s), and decoupling actuator DA2 nodes output signal y_22mb(s) sampled, And calculate the system output signal y of close loop control circuit 2₂(s) with feedback signal y_2b, and y (s)₂(s)=y₂₂(s)+y₂₁(s) And y_2b(s)=y₂(s)-y_22mb(s)；

D3：By feedback signal y_2b(s), fed back by the feedback network path of close loop control circuit 2 to controller C2 node-node transmissions Signal y_2b(s) will experience network transfer delay τ₄Afterwards, controller C2 nodes are got to；

The step of mode E, includes：

E1：Controller C2 nodes work in event driven manner, by feedback signal y_2b(s) triggered；

E2：In controller C2 nodes, by the system Setting signal x of close loop control circuit 2₂(s) feedback signal y, is subtracted_2b(s), Obtain deviation signal e₂(s), i.e. e₂(s)=x₂(s)-y_2b(s)；

E3：To e₂(s) IMC algorithms C is implemented_2IMC(s) IMC signals u, is obtained₂(s)；

E4：By IMC signals u₂(s) the feedforward network path of close loop control circuit 2 is passed throughUnit to decoupling actuator DA2 nodes Transmission, IMC signals u₂(s) will experience network transfer delay τ₃Afterwards, get to decouple actuator DA2 nodes；

The step of mode F, includes：

F1：Decoupling actuator DA2 nodes work in event driven manner, by IMC signals u₂(s) or by from cross decoupling net Network transmission channelThe output signal y of unit_p21(s) triggered；

F2：By IMC signals u₂(s) controlled device prediction model G is acted on_22m(s) its output valve y is obtained_22mb(s)；

F3：By IMC signals u₂(s) cross decoupling passage P is acted on₁₂(s) unit obtains its output signal y_p12(s)；

F4：By signal y_p12(s) cross decoupling network transmission channels are passed throughUnit, is performed to the decoupling of close loop control circuit 1 Device DA1 node-node transmissions；Signal y_p12(s) will experience network transfer delay τ₁₂Afterwards, get to decouple actuator DA1 nodes；

F5：By IMC signals u₂(s) the IMC signals u of actuator DA1 nodes is decoupled with coming from close loop control circuit 1₁(s) pass through Cross decoupling passage P₂₁(s) unit and cross decoupling network transmission channelsThe output signal y of unit_p21(s) subtract each other and obtain letter Number u_2p(s), i.e. u_2p(s)=u₂(s)-y_p21(s)；

F6：By signal u_2p(s) controlled device G is acted on₂₂(s) its output valve y is obtained₁₁(s)；By signal u_2p(s) act on controlled Object cross aisle transmission function G₁₂(s) its output valve y is obtained₁₂(s)；So as to realize to controlled device G₂₂And G (s)₁₂(s) Decoupling and control, while realizing to network random delay τ₃And τ₄Compensation and IMC.

2. according to the method described in claim 1, it is characterised in that：From TITO-NDCS structures, realize that system does not include control The predict-compensate model of all-network time delay in loop 1 and control loop 2, so as to exempt to random network delay, τ between node₁ And τ₂, and τ₃And τ₄Measurement, estimation or recognize, exempt the requirement synchronous to node clock signal.

3. according to the method described in claim 1, it is characterised in that：Realized from TITO-NDCS structures, network delay is compensated The implementation of method, the selection with specific network communication protocol is unrelated.

4. according to the method described in claim 1, it is characterised in that：Control loop 1 and control loop 2 in TITO-NDCS：Its Internal mode controller is respectively C_1IMCAnd C (s)_2IMC(s)；The equal only one of which of adjustable parameter in its loop, respectively λ₁And λ₂Parameter, The regulation of its parameter is simple with selection, and explicit physical meaning；Stability, the tracing property of system can be not only improved using IMC Energy and interference free performance, but also the compensation to random network time delay and IMC can be realized.