Tobit Kalman fusion filtering under dynamic event-triggering protocol with token bucket specification
Abstract
This paper addresses the multi-sensor fusion filtering problem for a class of linear discrete time-varying systems with censored measurement, described by the Tobit model, and scheduled by dynamic event-triggering protocols with token bucket specification. A dynamic event-triggering mechanism is first used to determine whether to transmit measurements under the token bucket specification, allowing transmission only if there are sufficient tokens and if the event-triggering condition is satisfied. Next, two indicator variables are denoted to represent the combined impact of the dynamic event-triggering protocol and the token bucket specification. A local Tobit Kalman filtering algorithm is then designed for each node by minimizing the trace of the filtering error covariance matrix under censoring and information transmission protocols' influence. Subsequently, all local estimates from each node are transmitted to the fusion center, where global estimates are generated using a federal fusion rule. The global estimates with suitable weights are sent back to every node for predictions at subsequent time instants. Finally, an illustrative simulation example is used to evaluate performance of this fused filtering scheme proposed in this paper.
Keywords
1. INTRODUCTION
As is well known, multi-sensor fusion filtering (MSFF) refers to the integration of information from different sensors to enhance the performance of the filtering scheme[1]. To date, multi-sensor information fusion technology has been extensively applied in a variety of fields, including target localization[2,3], fault detection[4], environmental monitoring[5], signal processing[6], image processing[7], etc. In general, multi-sensor fusion falls into two categories: centralized and distributed[8]. In the former, the raw data from each sensor is directly transmitted to the fusion center for filtering processing[9]. In contrast, the latter manner involves the fusion center integrating available estimates from local filters to generate optimal or suboptimal estimates[10]. While the precision of distributed fusion filtering may not match that of centralized fusion, its advantages include reducing the burden on the central processor, lowering communication bandwidth requirements, and enhancing system reliability and robustness. These distinguished advantages have led to widespread attention towards distributed fusion filtering schemes in recent years[11].
In networked control systems, due to harsh environmental conditions, limitations in sensor capabilities, poor signal transmission line quality, and hardware or software failures in sensors, nonlinearities are inevitable in the actual system measurement output. These nonlinearities include, but are not limited to, censoring[12], channel fading[13], quantization[14], saturation[15], etc. If not handled properly, these nonlinear factors may even affect the stability of the filtering error system. When designing and implementing filters in networked systems, it is necessary to fully consider the impact of these nonlinear factors and take effective measures to minimize their impact on system performance to ensure system stability and reliability. At present, for addressing nonlinear challenges and improving filtering accuracy and stability, various nonlinear filtering algorithms have been proposed, such as the extended Kalman filtering (EKF)[16], the unscented Kalman filtering (UKF)[17], and the Tobit Kalman filtering (TKF)[18].
Because of the limited sensing abilities of low-cost sensors, the censored measurements are prevalent in practical engineering[19]. The censored measurements are commonly formulated by the Tobit model, which is widely used in data analysis in economics, finance, and social sciences. This model can effectively handle problems involving censored data and provides estimates of unobserved variables. When the measurement noise of a system exhibits non-Gaussian characteristics near the censoring region, traditional Kalman filtering methods cannot handle it. The primary challenge induced by the censored measurements lies in its nonlinearities. A useful method is to introduce the indicator variable to transform the piecewise linear functions into a unified form in[20], which will provide convenience for performance analysis and deal with the scalable distributed H
Allik et al. have designed TKF for the first time by using the Tobit model, where the unilateral and bilateral Tobit regression models are integrated into the recursive form of the Kalman filter[23]. In a comparison of TKF and KF, it can be found that when data is not censored, there is no difference between these two filters; when data is censored, the extra computational burden of TKF mainly comes from the calculation of occurrence of censoring measurement. Nevertheless, it fails to fully explore and utilize the useful information contained in the censored region. To address this problem, Han et al. have developed a novel conditional expectation approach to study TKF problem for stochastic parameter systems[24]. Subsequent research regarding TKF has been published by combining with other interesting phenomena, such as dynamic bias and Round-Robin protocol[25], fading measurements[26], dynamic event-triggered protocols (DETPs)[27], and so on.
Although there are currently a large number of research results on TKF, the Tobit Kalman fusion filtering (TKFF) has not received sufficient attention due primarily to its complexities in analysis. The core step of this paper is to select an appropriate fusion rule from various existing fusion rules and combine it with local TKFs. The well-known fusion rules include centralized filtering fusion[28], information filtering fusion[29], weighted filtering fusion[30], covariance intersection fusion[31], federated filtering fusion[10], sequential fusion[32], and robust fusion[33]. In the survey paper[34], these fusion rules are compared in terms of the structure of the fusion, filtering accuracy, and computation burden, respectively. Federated filtering fusion belongs to a distributed structure and has the smallest burden and highest accuracy. As a result, we choose federated filtering fusion for this paper.
In the past decades, networked systems have gained popularity owing to multiple advantages such as high flexibility, simple installation, and low cost, making them suitable for a range of applications including aerospace, energy monitoring, and telecommunications[35]. Unlike traditional automatic control systems, the focus of networked systems explicitly considers the limitations of the communication medium between the sensor and the controller/filter. Especially when network congestion occurs, where the allocation of requests exceeds the network's sustainable transmission rate, these limitations become even more evident, which would pose a serious impact on the desirable performance. A well-established paradigm for addressing this issue is event-triggered protocol[36]. The idea of event-triggered protocol is to reduce the transmission number only if the event-triggering condition is satisfied. Such a protocol can efficiently save the communication resource[37]. However, it cannot be guaranteed that the transmission network will not be overused, especially when the desired performance level requires a high transmission rate. In the existing references[36,37], the event-triggering protocol (ETP) is introduced to save unilaterally the network bandwidth resource in the premise of a certain performance by reducing the number of information transmissions. Nonetheless, such a protocol cannot be appropriate for practical engineering scenarios. In a shared network with limited bandwidth, when encountering multiple requests of information transmission, it is difficult to have enough bandwidth resources.
It should be noted that the total communication resource cannot be formulated in the existing results and thus the role of the ETP cannot be reflected in a unified framework. Recently, a dynamic model has been used to describe the network resources: the token bucket algorithm[38,39], where the network's communication resources are considered and the signal transmission is triggered only when the network's communication capabilities allow. The level of the bucket reflects the network's current communication capabilities. The objective of these studies is to optimally utilize limited communication resources by combining control inputs with triggering mechanisms[40]. Inspired by such an idea, an interesting problem is to explore how the token bucket algorithm can be integrated with communication protocols, to more reasonably allocate tokens for network requests and achieve optimized resource utilization. In line with this concept, an intriguing issue is to investigate the integration of the token bucket algorithm with DETPs within a unified framework for studying TKFF. This constitutes another motivation for the present paper.
Enlightened by the above arguments, the objective is to investigate the federated TKFF (FTKFF) problem under the schedule of dynamic event-triggered protocols with token bucket specification. The main contributions of this paper are highlighted as follows: (1) an FTKFF problem is studied under the combined schedule of the token buckets and DETPs, where the former characterizes the limited communication resources and the latter determines the necessary information to be transmitted; (2) a recursive local filter is designed, where two indicator variables are introduced to formulate the transmitted censored measurements, and the gain matrix is derived by minimizing the upper bound of the filtering error covariance; (3) the federated fusion criterion is chosen in the fusion center to obtain an optimal estimation by using the local estimates.
Notations:
2. PROBLEM FORMULATION
2.1. System model
Consider the state-space model for a class of linear discrete time-varying systems and its measurements from
where
The situation where one or multiple sensors cannot perform data measurement or acquisition properly for various reasons is referred to as "censored measurements". To address the issue of censored measurements and mitigate its adverse impact on system monitoring, the Tobit measurement model is used to formulate the one-side censored measurement:
where
In light of (2), define a series of Bernoulli random variables
which obeys the distribution law:
where
The censoring probability
where
Similar to[12], the measurement expectation and variance of
where
Here,
Denote
Also, the following statistical information can be obtained from (6) and (7):
and
Remark 1.The censoring measurement is formulated as the Tobit model. The main challenge in dealing with the Tobit model arises from two aspects. Firstly, the Tobit model (2) represents a piecewise linear function, which is inherently nonlinear. To facilitate subsequent analysis, a random variable defined in (3) is introduced to reformulate the censoring measurement into a uniform form (8). Another issue involves determining the probability law and statistical property of the random variable (i.e., (5), (6), and (7)), where (5) is derived by using statistical information of normal distribution of measurement noise
2.2. Information transmission protocols
To save precious energy and limited bandwidth, the DETP is used for node
where
where
is referred to as the event-triggering condition. For convenience, define the following indicator variable:
To cope with the measurement transmission in unexpected situations, such as the need to transfer multiple data at once, a token bucket triggering mechanism is introduced. First, the token bucket is employed to describe the available bandwidth resource, where the integer
In order to unify the centralized utilization of the token bucket algorithm, the number of tokens is then evenly allocated to each sensor node, which is given as follows:
The internal token change of the token bucket is formulated as follows:
with initial values
After scheduled by the DETP with token bucket specification, the measurement received by the filter is formulated as
For the convenience of later analysis, (19) is rewritten as
Remark 2.Different from[30], the introduction of the indicator variable
The block diagram of FTKFF is depicted in Figure 1. As for node
2.3. Filter design
By using the available measurement
with the initial value
The primary objective of this paper is to design a local filter of the form (21) and (22) for every node under the DETP with token bucket specifications for all censored measurements within the framework of TKF. Moreover, we are devoted to developing an FTKFF framework to address the multiple challenges induced by the censored measurements, the DETP and the token bucket specifications.
3. MAIN RESULTS
This section introduces the recursive bound of the TKF of the filtering error covariance. In addition, the desired filter gain is calculated based on the minimum mean square error criterion.
3.1. Filtering error and covariance matrix
In line with (5) and (6), the estimate of the measurement
where
Let
Subsequently, from (1), (8), (22) and (23), one has
where
By means of Eqs. (24) and (25), the covariance matrices of the prediction error and filtering error are, respectively, calculated as follows
and
where
Next, an upper bound for the filtering error covariance matrix
Theorem 1.For the given positive scalars
with the initial value of
and
where
and
where
Here,
Proof. According to lemma 1 in[36], it follows from Eq. (27) that
Following the same line, one has
Moreover, given the event-triggering condition (11), we have
In light of lemma 5 and the proof of lemma 4 in[27], one derives
Substituting Eqs. (32) and (34) into (31), one obtains the following inequality
By using lemma 2 in[27], one obtains that
The proof is now complete.
Next, the filter gain
Theorem 2.Suppose that the positive scalars
where
Proof. First, calculate the trace of
Next, one can derive the derivative of
By letting (39) be zero, one acquires the filter gain as follows:
As such, one completes the proof of this theorem.
Remark 3.Different from the approach to dealing with the DETP in[6,27,37], an indicator variable is employed to formulate the impact of the DETP. From (37), it can be observed that the filter gain
3.2. Boundedness analysis
In this section, the boundedness of
Assumption 1.Suppose that the following inequalities hold
where
Theorem 3.Suppose Assumption 1 holds, in line with the system (1) and censored measurement (2) under Assumption 1, if the following inequality holds:
where
where
Proof. In line with Assumption 1 and Eq. (26), it deduces that
By noting Eqs. (37) with (40), the upper bound of the filter gain
from which can be gained from Eq. (30):
By means of
In the following, we can rewrite (47) as follows
which further implies
If (42) holds, i.e.,
Remark 4.Theorem 3 shows the combined impact of the DETP with the token bucket specifications on the filtering error boundedness and the filtering accuracy. Noticing that
3.3. Federated Tobit Kalman fusion filtering
In line with federated filtering fusion, the state estimate and the error covariance are
Theorem 4.The FTKFF scheme for systems (1)-(2) is expressed as
with the resulting updated values
where
It is noted that the role of (51) is to allocate the fused result to the individual sub-filter. The detailed procedure of FTKFF is summarized in Algorithm 1.
Algorithm 1 FTKFF 1: for m=1:l do
2: Initialization:
3: end for
4: for t=1:N do
5: for m=1:l do
6: Execute information transmission protocols
7: determine
8: determine
9: if
10:
11: else
12:
13: end if
14: Execute Local filtering
15: Calculate
16: Calculate
17: Compute the filter gain
18: Calculate
19: Compute
20: end for
21: Execute fusion filtering
22: Compute
23: Update the number of tokens by (17)
24: Tokens are assigned to every node by (16)
25: Update
26: end for
In line with the boundedness analysis of Theorem 3, the same argument can be applied to deduce the boundedness.
According to Algorithm 1, one has the computational complexity of the scheme developed in this paper.
Remark 5.Now, we focus on the computational complexity of the scheme. In light of the system dimensions, such as
In the following, we will discuss the consistency of the federated fusion.
Theorem 5.If
Proof. First of all, one calculates
Noting such a fact:
one derives that
According to (49), one further has
which indicates that
By resorting to lemma 2 in[41], one derives
Now, the proof is complete.
Remark 6.The FTKFF scheme is proposed for a class of discrete time-varying systems under the schedule of the DETP with token bucket specifications. This paper embodies the following significant characteristics from two viewpoints: (1) a local Tobit Kalman filter (LTKFs) is elaborately designed based on an enhanced protocol model that gives combined consideration of the impacts incurred by the DETP and token bucket specifications, where two indicator variables are used to formulate their roles; (2) a federated fusion rule is chosen by productively integrating the local estimates from LTKFs.
4. AN ILLUSTRATION EXAMPLE
In this section, an oscillator simulation example in[10,12] is provided to showcase the effectiveness of the proposed FTKFF algorithm, under the schedule of the dynamic event-triggering with tokens buckets. The system parameters are chosen as
In terms of the token bucket formulation, choose the following parameters
The corresponding parameters in the dynamic event-triggering conditions (14) are set to be
The simulation results are displayed in Figures 2-10. Figure 2 depicts the utilization of communication resources under the schedule of dynamic event-triggered protocol with the token bucket specifications in the network, where the black asterisk, blue circle, and red cross are denoted as the event-triggering time instant of Node
8. The logarithm of
9. The logarithm of
10. The logarithm of
In Figures 5-7, the blue curve represents the estimates from the local filters. Due to the existence of censored measurements, there exist obvious fluctuations of the local estimate, especially in the estimation of state
In Figures 8-10, the red curve represents the upper bound of the covariance of the local estimation error, while the yellow curve shows that of the filtering error after fusion. It can be observed that the result after fusion is better than that before fusion. Additionally, the blue dashed line represents the mean square error of the local estimator; the black curve indicates that after fusion. It can be noticed that in most cases, the mean square error of fused results is almost smaller than that of the local estimates, and the error curve is relatively smooth. This also demonstrates the superiority of the FTKFF scheme.
Thanks to the regulations of federated fusion filtering, distributed processing is achieved among sensors, where each local filter enhances the real-time performance of the system. Even in cases where a sensor fails or provides inaccurate information, the fusion center can enhance the filter's performance by utilizing data from other nodes and transmitting it to the local filter, resulting in a smoother filtered state value, which implies that the system becomes more resilient. As shown in Figures 8-10, the upper bound of the trace of the fused filtering error covariance matrix is smaller than that of a single node, and there is also an improvement in terms of mean square error. Therefore, the FTKFF scheme developed in this paper is indeed effective.
5. CONCLUSIONS
This paper has proposed a class of FTKFF schemes with censored measurements under the schedule of dynamic event-triggering with token specifications. First, the Tobit model has been used to describe the censored measurements. The token bucket traffic shaping algorithm with DETPs has been integrated to fully utilize limited communication resources. A local recursive filtering scheme has been designed for every node and an upper bound for the covariance matrix of the filtering error has been derived in the sense of trace. By minimizing this upper bound at each time step, the local filter gain has been calculated recursively. Additionally, sufficient conditions for the local filtering error to be mean-square stable are derived by analyzing the boundedness of the local filtering error covariance matrix. The fusion center processes the local filtering values at each time step via the federated fusion rule and distributes the fused results to each local filter. This comprehensive fusion filtering framework provides an effective solution to the censored measurements and information transmission protocol involving the DETP and token bucket specifications. Finally, the performance of the proposed FTKFF scheme is evaluated through a simulation example. In the future, the schemes proposed in this paper could be further developed to deal with more complicated cases such as sensor saturation, uncertain parameter systems, signal quantization, and time-delay systems or two-side censored measurements.
DECLARATIONS
Authors' contributions
Conceptualization and manuscript drafting: Chen X
Methodology and experiment: Zhang J
Manuscript edition: Song Y
Review and supervision: Han F
Availability of data and materials
Not applicable.
Financial support and sponsorship
This work was supported in part by the National Natural Science Foundation of China under Grants 62073070 and U21A2019.
Conflicts of interest
Han F is a Junior Editorial Board Member of the journal Complex Engineering Systems, while the other authors have declared that they have no conflicts of interest.
Ethical approval and consent to participate
Not applicable.
Consent for publication
Not applicable.
Copyright
© The Author(s) 2024.
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Cite This Article
How to Cite
Chen, X.; Han, F.; Song, Y.; Zhang, J. Tobit Kalman fusion filtering under dynamic event-triggering protocol with token bucket specification. Complex Eng. Syst. 2024, 4, 19. http://dx.doi.org/10.20517/ces.2024.37
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