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Article

Suspension Parameter Estimation Method for Heavy-Duty Freight Trains Based on Deep Learning

1
College of Railway Transportation, Hunan University of Technology, Zhuzhou 412007, China
2
College of Electrical and Information Engineering, Hunan University of Technology, Zhuzhou 412007, China
*
Author to whom correspondence should be addressed.
Big Data Cogn. Comput. 2024, 8(12), 181; https://doi.org/10.3390/bdcc8120181
Submission received: 13 October 2024 / Revised: 20 November 2024 / Accepted: 2 December 2024 / Published: 4 December 2024
(This article belongs to the Special Issue Perception and Detection of Intelligent Vision)
Figure 1
<p>Overall block diagram of CNN-GRU parameter estimation algorithm.</p> ">
Figure 2
<p>Sensitivity analysis results of dynamical parameters.</p> ">
Figure 3
<p>Architecture of the CNN-GRU agent model.</p> ">
Figure 4
<p>Comparison of SIMPACK simulation values and model prediction values.</p> ">
Figure 5
<p>Instrumented wheelset detection system.</p> ">
Figure 6
<p>Schematic depiction of the NSGA-II principle.</p> ">
Figure 7
<p>Flow diagram of NSGA-II.</p> ">
Figure 8
<p>Convergence of primary suspension longitudinal stiffness.</p> ">
Figure 9
<p>The Pareto frontier of NSGA-II.</p> ">
Figure 10
<p>Comparison of predicted and simulated values of wheel–track lateral interaction force by different combinations of models and algorithms.</p> ">
Figure 10 Cont.
<p>Comparison of predicted and simulated values of wheel–track lateral interaction force by different combinations of models and algorithms.</p> ">
Figure 11
<p>Comparison of predicted and simulated values of wheel–track vertical interaction force by integrating various models and algorithms.</p> ">
Figure 11 Cont.
<p>Comparison of predicted and simulated values of wheel–track vertical interaction force by integrating various models and algorithms.</p> ">
Figure 12
<p>Comparison of simulated and measured values of wheel–track lateral interaction force before and after using the estimated parameters.</p> ">
Figure 13
<p>Comparison of simulated and real-world values of wheel–track lateral interaction force after using the estimated parameters.</p> ">
Versions Notes

Abstract

:
The suspension parameters of heavy-duty freight trains can deviate from their initial design values due to material aging and performance degradation. While traditional multibody dynamics simulation models are usually designed for fixed working conditions, it is difficult for them to adequately analyze the safety status of the vehicle–line system in actual operation. To address this issue, this research provides a suspension parameter estimation technique based on CNN-GRU. Firstly, a prototype C80 train was utilized to build a simulation model for multibody dynamics. Secondly, six key suspension parameters for wheel–rail force were selected using the Sobol global sensitivity analysis method. Then, a CNN-GRU proxy model was constructed, with the actually measured wheel–rail forces as a reference. By combining this approach with NSGA-II (Non-dominated Sorting Genetic Algorithm II), the key suspension parameters were calculated. Finally, the estimated parameter values were applied into the vehicle–line coupled multibody dynamical model and validated. The results show that, with the corrected dynamical model, the relative errors of the simulated wheel–rail force are reduced from 9.28%, 6.24% and 18.11% to 7%, 4.52% and 10.44%, corresponding to straight, curve, and long and steep uphill conditions, respectively. The wheel–rail force simulation’s precision is increased, indicating that the proposed method is effective in estimating the suspension parameters for heavy-duty freight trains.

1. Introduction

As demand for the transportation of heavy-duty freight trains increases, trains are operating with higher loads under complex and changing line conditions. The effectiveness and safety of the overall transportation system are closely correlated with the operational safety and stability of trains [1,2]. The suspension system is the core structural component supporting the stable running of heavy-duty freight trains. Therefore, the design and adjustment of its parameters are particularly important. However, during long service, the parameters of suspension systems for heavy-duty freight trains can deviate from their initial design values due to material aging and performance degradation, resulting in a decrease in vehicle dynamics performance [3,4]. As traditional multibody dynamics simulation models are usually designed for fixed working conditions, it is difficult for them to fully and accurately assess the status of the vehicle–line system. For this reason, it is crucial to use advanced machine learning techniques and data-driven methods to estimate and optimize suspension parameters.
In the field of track–vehicle system identification and parameter estimation, the research can be broadly classified into two directions, i.e., numerical estimation methods based on track–vehicle dynamics simulation modeling [5,6] and methods based on machine learning [7,8,9]. Among them, as one of the machine learning methods [10,11], the proxy model, combined with a deep learning model, can effectively capture comprehensive dynamic characteristics of trains during operation, simplify the original complex model and derive accurate results faster, such that the safety and reliability of the transportation system can be improved. Mohamed et al. [12] sought to optimize a passive vehicle suspension system by using the HHO (Harris Hawk Optimization) algorithm. Qing et al. [13] discussed an approximate Bayesian method to accurately estimate the suspension characteristics of high-speed trains in operation. Zou [14] used a surrogate model to replace the high-precision dynamical model, for the purpose of developing a quick optimization technique for suspension parameters under various circumstances. Pan et al. [15] comprehensively studied various machine learning methods in the field of estimating suspension parameters.
To achieve the accurate estimation of suspension parameters for heavy-duty freight trains, this paper utilizes actual values of wheel–rail force measurements from heavy-duty freight trains, constructs a proxy model based on CNN-GRU, and combines sensitivity analysis and an optimization algorithm. Figure 1 depicts the overall procedure, and the primary contributions of the method are as follows:
(1)
A database of wheel–track interaction force values recorded by the force measuring system is established, including wheel–track interaction force data under three typical working conditions, i.e., straight, curve, and long and heavy uphill conditions. This provides reliable data for the training of the proxy model;
(2)
A suspension parameter estimation method is proposed. It is data-driven and based on the mechanism model. Using a proxy model and an optimization algorithm, it estimates the suspension parameters, providing a new approach to accurately evaluate the safety state of heavy-duty freight trains;
(3)
The proposed method’s usefulness is demonstrated through comparative trials, resulting in a new approach for ensuring vehicle safety and stability.

2. Establishment of a Multibody Dynamic Model for the Vehicle–Line and Determination of Key Parameters

In this section, a multibody dynamics model of vehicle and track interaction is established. The model’s complexity is then reduced by performing a sensitivity analysis to discover which parameters have a greater influence on its wheel–rail force output.

2.1. Multibody Dynamics Model of Vehicle and Track Interaction

With the data of a Chinese C80 heavy-haul freight train taken as the primary modeling parameters, as presented in Table 1 [16], a vehicle–line coupling multibody dynamic model was constructed by adopting SIMPACK 2018. The car body is represented using K6 bogie, and the rigid parts such as the wheelset, axle box and frame relate to each other by force elements. The primary spring and the primary vertical shock absorber are constructed from linear force elements and nonlinear viscoelastic force elements, respectively. The wheelset and the frame are linked via the primary suspension system, and the secondary suspension consists of the secondary lateral shock absorber, an anti-yaw shock absorber, etc. The frame and the car body are connected through the secondary suspension system [17,18]. The contact at the interface of the track and wheelset was examined using Hertz contact theory. The wheelset thread is considered as an LMA worn tread, and wheel–track rolling contact modeling was carried out using the FASTSIM algorithm. The track irregularity excitation was calculated using the American Class V track spectrum.

2.2. Determination of Key Parameters of Train-Line Coupling Multibody Dynamic Model

According to relevant experience and expert knowledge, the 10 suspension parameters X11~X20 shown in Table 1 have important impacts on the vehicle suspension system [13,19,20]; therefore, they are defined as the main suspension parameters. To simplify the structure of the proxy model, a sensitivity analysis method is further adopted to screen the most critical influencing parameters out of these main suspension parameters. The process is as follows:
(1) Taking wheel–rail force as the optimization target, 1000 samples of each of these 10 suspension parameters were taken randomly using the LHS (Latin hypercube sampling) method [21] within their respective parameter ranges. The specific sampling range is shown in Table 2.
(2) The Sobol global sensitivity analysis method was used [22,23] to assess how input parameters affect the model’s output. It can assess the impact of the input dynamical parameters on the variation of wheel–track forces. Based on the values of 10 suspension parameters sampled using the Latin hypercube method and the corresponding forces acting vertically and laterally on the wheels and rails, the global sensitivity coefficients S t of parameters X11–X20 to wheel–rail forces were calculated, and the sensitivity analysis results are shown in Figure 2.
The larger the sensitivity coefficient, the greater the influence of the parameter on the target; conversely, the lower the coefficient, the smaller the impact of the parameter on the target. As shown in Figure 2, parameters X14, X15, X16 and X18 have greater effects on wheel–track lateral interaction force, while X13, X15 and X17 have a greater effect on wheel–track vertical interaction force. Based on the above results, these six parameters were defined as key suspension parameters.

3. Construction of the CNN-GRU Proxy Model

With the advancement of deep learning technologies, neural network models are widely used in various fields, showing great performance, especially in processing time-series data. As a feedforward neural network, the Convolutional Neural Network [24] is particularly suitable for image recognition and signal processing tasks. It captures the spatial structural characteristics of input data through local connections and weight sharing mechanisms. CNN can be used to extract spatiotemporal characteristics of the vehicle movement data, for instance, wheel–track interaction forces, acceleration values, and other time-varying patterns of signals. The GRU (gated recurrent unit) [25] is derived from the LSTM network. It has a simplified LSTM structure while maintaining a capacity for handling long-range dependence. The GRU regulates the flow of information by creating update and reset gates, allowing the network to better remember past information and ignore irrelevant information.
In this section, a CNN-GRU hybrid model is proposed, leveraging the feature extraction capabilities of CNN and the strong capacity of GRU for time-series prediction. The hybrid model’s purpose is to extract key characteristics from the primitive vehicle movement data using CNN and to construct a time-evolution model for these features through GRU, so that an efficient estimation of suspension parameters can finally be achieved. The proposed model’s structure is illustrated in Figure 3.
The input of the proxy model is the values screened out by a sensitivity analysis of the six key suspension parameters already defined. Each parameter contains data of 1000 time steps, the data for each time step are collected at three different time points, forming twenty-one features, forming a total of six channels. The outputs of the model are wheel–track lateral interaction force and vertical interaction force. To generate training data, a sliding window was used for sampling, employing a 20 × 21 window and a step increment of one. It generated 980 small fragments arranged in time order, each of which is a 20 × 21 matrix. The overall operation procedure is as follows:
(1)
Convolutional layers are mainly used to extract spatial features from input data. A one-dimensional convolution kernel with dimensions [1,1] and a step increment of one was adopted to ensure effective feature extraction. In the first round of convolution, 21 depths were set, with a step size of 1, using the activation function ReLU. The depth of the second round of convolution was increased to 128, and the LeakyReLU activation function was used to capture nonlinear features. Then, down sampling was performed through the max pooling layer with a [2,1] window and a step interval of one. This aids in lowering the number of parameters and extracting key features, while maintaining timing continuity. Via the above processing approach, each small fragment was transformed into feature data with 64 channels. To reduce the likelihood of overfitting, a dropout layer was introduced with a value of 0.2;
(2)
To capture the temporal dependencies in these feature data, gated recurrent units were added to the model. The GRU layer is able to analyze the data in both forward and reverse directions, enabling us to more comprehensively mine the contextual information in time-series data. We then adopted a three-layer GRU. The number of hidden units in GRU layer 1 was 64, with the input being feature data processed through convolution and pooling. GRU layer 2 had 32 hidden units, and GRU layer 3 had 16 hidden units. The results from the GRU layer were fed into the fully connected layers. The numbers of elements in the fully connected layers were 64, 8, and 1, respectively, ensuring that the model was able to gradually map high-dimensional features to low-dimensional wheel–track interaction forces;
(3)
The forecast output values of wheel–track interaction forces were compared with the simulated values to validate the model’s accuracy. The outcomes are depicted in Figure 4.

4. Dynamic Parameter Estimation Based on Measured Data

In this section, the suspension parameters of C80 heavy-duty freight trains were estimated using NSGA-II, with the help of the above CNN-GRU model and the measured data.

4.1. Introduction of Instrumented Wheelset

The measured wheel–track interaction force data used in this paper were derived from a heavy-freight transportation line in China. Figure 5 demonstrates the instrumented wheelset installed in the heavy-duty freight train. It can facilitate the real-time measurement of the wheel–track interaction force. The force-measuring wheelset can continuously capture key mechanical data during the running of the freight train, providing an important basis for vehicle dynamics analysis and suspension parameter estimation.

4.2. NSGA-II Parameter Estimation Based on the Proxy Model

Compared with traditional genetic algorithms, NSGA-II (Non-dominated Sorting Genetic Algorithm II) [26,27] adopts the concepts of fast non-dominated sorting and crowding. This significantly increases the rate at which iterations converge, significantly lowers computational complexity, and guarantees population variety so that the optimal solution set can be found among multiple and conflicting objectives. With certain constraints, NSGA-II can find the best combination of suspension parameters. Its principle is illustrated in Figure 6.
The core idea of NSGA-II is to perform non-dominant sorting on the population and select excellent individuals for genetic operation according to the sorting results and crowding information. First, an initial population Pt is randomly generated. It contains a certain number of individuals. Each one represents a possible solution consisting of a set of decision variables, ranked in a non-dominated fashion according to the individual’s objective function value. The non-dominant hierarchy defines the criteria for one individual to be better than another, i.e., an individual is better than another if it outperforms the other in all goal functions. Through non-dominated sorting, the population can be divided into multiple frontiers (F1, F2, F3, …). For each individual on the frontier, the crowding distance between them is computed. This facilitates the consideration of diversity and distribution when selecting new population members. A new candidate population Qt is generated through hybridization and mutation operations. The original population and the newly generated candidate population are then merged. By comparing the non-dominated level and crowding distance of individuals in the two populations, the highest-performing individuals are selected to be part of the next population. The algorithm’s flow is illustrated in Figure 7.
In this section, the main research objective is to minimize the difference between simulated and measured wheel–rail forces. Taking the sensitivity analysis results in Section 2.2 as the design variables, considering that the wheel–rail force includes vertical and lateral forces, the wheel–rail force is divided into two components. The specific objectives are to compare the difference between the predicted wheel–rail lateral force from simulated data and the actual measured wheel–rail lateral force, as well as the difference between the predicted wheel–rail vertical force from simulated data and the actual measured wheel–rail vertical force. The optimization objectives are determined as follows:
min y ^ i y i
The following parameters were used: population size 50, crossover probability 0.9, mutation probability 0.05, and 100 iterations. Figure 8 illustrates the convergence of X13. It is discernible that X13 gradually converges to a certain stable value and fluctuates slightly around this value.
After the optimization calculation, Figure 9 shows the Pareto front of NSGA-II. Table 3 and Table 4 provide some information about NSGA-II during operation, where the first column represents the current number of iterations, the second column represents the total number of evaluated individuals, the third column represents the number of non-dominated solutions, the fourth column represents the convergence index, and the fifth column represents the evaluation index. Ideal indicates that the current solution set is close to the ideal solution, f indicates that there is no significant change in the current solution set, and nadir indicates that the current solution set is closest to the worst solution. In the later stage of optimization, a smaller EPS value indicates that the solution set is close to the optimal solution. The indicator is mainly f, indicating that the solution set tends to be stable.
We substituted the corrected results into the vehicle–line coupled multibody dynamics model, and the initial values and estimated results of key dynamic parameters are listed in Table 5.

5. Experiment Result Analysis

This section describes the experiment and its outcomes in depth. Considering the complexity of each working condition, only three working circumstances, i.e., straight line, curved line, and long and steep uphill, were considered for the wheel–track interaction force in the current work. The specific parameter settings of each working condition are shown in Table 6, while different settings of the same working condition type were not considered here.

5.1. Performance Comparison of Several Models

To better illustrate the efficacy of the method presented in this research, the CNN-GRU model is assessed alongside the RBF, CNN-LSTM, BP and CNN-BiLSTM models [28,29,30], as shown in Figure 10 and Figure 11. To more intuitively display the model’s forecast accuracy, the relative error was employed to assess the discrepancy between predicted and simulated values. The results are given in Table 7. The formula is as follows [31,32]:
Δ x x = y y i y i
where y represents the value predicted by various models, and y i represents the value simulated by the vehicle–line coupling multibody dynamic model.
As shown above, for wheel–track lateral interaction force, the RBF model has the highest relative error rate of 10.09%, whereas this value in the other models is relatively low, and the method proposed in this research has the lowest relative error ratio of 3.59%. For the values of wheel–track vertical interaction force, the numerical fluctuation is small, and the relative error rate of incidence of the proposed method is minimal, at 1.56%. In other words, the CNN-GRU model described in this paper can provide better forecasting accuracy.

5.2. Comparison of Wheel–Rail Forces Before and After Parameter Estimation

The parameter estimation results in Section 4.2 were introduced into the train–line coupling multibody dynamic model based on C80 data, and the simulated forces were compared with the forces measured by the instrumented wheelset, before and after using the estimated parameters. The wheel–rail lateral force results produced under three working conditions before and after parameter correction are shown in Figure 12 and Figure 13.
The simulated values of wheel–track lateral interaction force before and after using the estimated suspension parameters were compared separately with the measured force values, and relative error was used to evaluate the accuracy before and after the parameter correction. Table 8 and Table 9 present the results of the comparison between the simulated and real-world values of wheel–track lateral interaction force before and after parameter correction.
The statistics in Table 8 and Table 9 show that, under different working conditions, the error produced in simulating wheel–rail force is significantly improved after using the estimated suspension parameters, i.e., after the suspension parameters are corrected. Specifically, the error rate of the wheel–track lateral interaction force decreases from 9.28% to 7.00%, while the error of wheel–track vertical interaction force increases slightly from 0.93% to 1.17% under the straight-line condition. Under the curved-line condition, the error rate of wheel–track lateral interaction force decreases from 6.24% to 4.52%, and from 2.47% to 2.02% for the vertical force. Under the long and steep uphill conditions, the error rate of wheel–track lateral interaction force decreases greatly from 18.11% to 10.44%, and from 2.01% to 0.85% for the wheel–track vertical interaction force. These results show that the error between the simulated and real-world values of the wheel–track interaction force is significantly reduced by suspension parameter correction, especially under complex working conditions (such as curved line and long and steep uphill line). This fully demonstrates the efficacy of the strategy provided in this study in improving the accuracy of the simulation model and the operational safety of the train.

6. Conclusions

This paper aimed to achieve accurate estimation of the suspension parameters for heavy-duty freight trains by building a CNN-GRU proxy model combined with a sensitivity analysis and an optimization algorithm, and herein, we have conducted comparative experiments before and after using the estimated suspension parameters. The significant results are as follows:
(1)
For the C80 freight train, under the three typical working conditions mentioned in this paper, the primary suspension longitudinal stiffness, the secondary suspension vertical stiffness, and the secondary suspension lateral stiffness have stronger effects on the wheel–track vertical interaction force, while the primary lateral stiffness, primary vertical stiffness, secondary lateral shock absorber damping, and secondary longitudinal stiffness have greater effects on the wheel–track lateral interaction force;
(2)
Through comparative experiments, the effectiveness of the suggested CNN-GRU proxy model has been verified. The investigation results reveal that by using the optimized suspension parameters, the accuracy of the multibody dynamics simulation model was significantly elevated, and the peak value of the wheel–rail force was reduced, such that the risk of derailment was reduced, and the operational safety and stability of heavy-haul freight trains were effectively improved;
(3)
The NSGA-II algorithm based on the CNN-GRU model proposed in this work demonstrates remarkable effectiveness in the estimation of suspension parameters for heavy-duty freight trains. This method can more accurately identify changes in suspension parameters. It provides a new approach to augmenting the safety and stability of train operation.
The method proposed in this study is suitable for estimating the suspension parameters of C80 heavy-duty trucks. In future research, the generalizability of this method when using different vehicle types and operating conditions can be further explored so as to extend it to other types of transportation systems. By combining advanced machine learning technology and visual inspection methods, the real-time monitoring and dynamic adjustment of vehicle status can be realized to further improve the safety and efficiency of transportation systems. Future research can be devoted to exploring more complex conditions, a wider variety of suspension parameters, and how to apply these technologies to online monitoring and fault diagnosis systems used in actual operations so as to achieve more intelligent and automated transportation management.

Author Contributions

C.Z., conceptualization, methodology. Y.W., data analysis and writing. J.H., validation, English writing and providing guidance on the revision process. All authors have read and agreed to the published version of the manuscript.

Funding

This work is supported by the National Key R and D Program of China (2021YFF0501101), National Natural Science Foundation of China (62173137), and the Project of Hunan Provincial Department of Education (23A0426).

Data Availability Statement

The data presented in this study are available on request from the corresponding author since the data in this study come from a national key project.

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. Overall block diagram of CNN-GRU parameter estimation algorithm.
Figure 1. Overall block diagram of CNN-GRU parameter estimation algorithm.
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Figure 2. Sensitivity analysis results of dynamical parameters.
Figure 2. Sensitivity analysis results of dynamical parameters.
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Figure 3. Architecture of the CNN-GRU agent model.
Figure 3. Architecture of the CNN-GRU agent model.
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Figure 4. Comparison of SIMPACK simulation values and model prediction values.
Figure 4. Comparison of SIMPACK simulation values and model prediction values.
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Figure 5. Instrumented wheelset detection system.
Figure 5. Instrumented wheelset detection system.
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Figure 6. Schematic depiction of the NSGA-II principle.
Figure 6. Schematic depiction of the NSGA-II principle.
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Figure 7. Flow diagram of NSGA-II.
Figure 7. Flow diagram of NSGA-II.
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Figure 8. Convergence of primary suspension longitudinal stiffness.
Figure 8. Convergence of primary suspension longitudinal stiffness.
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Figure 9. The Pareto frontier of NSGA-II.
Figure 9. The Pareto frontier of NSGA-II.
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Figure 10. Comparison of predicted and simulated values of wheel–track lateral interaction force by different combinations of models and algorithms.
Figure 10. Comparison of predicted and simulated values of wheel–track lateral interaction force by different combinations of models and algorithms.
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Figure 11. Comparison of predicted and simulated values of wheel–track vertical interaction force by integrating various models and algorithms.
Figure 11. Comparison of predicted and simulated values of wheel–track vertical interaction force by integrating various models and algorithms.
Bdcc 08 00181 g011aBdcc 08 00181 g011b
Figure 12. Comparison of simulated and measured values of wheel–track lateral interaction force before and after using the estimated parameters.
Figure 12. Comparison of simulated and measured values of wheel–track lateral interaction force before and after using the estimated parameters.
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Figure 13. Comparison of simulated and real-world values of wheel–track lateral interaction force after using the estimated parameters.
Figure 13. Comparison of simulated and real-world values of wheel–track lateral interaction force after using the estimated parameters.
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Table 1. Core parameters of the vehicle–track coupled system model.
Table 1. Core parameters of the vehicle–track coupled system model.
Dynamical ParameterSymbolInitial Value
Wheelset weight/(kg)X11200
Wheelset rolling moment of inertia (relative to center of mass)/(kg·m2)X2800
Wheelset pitching moment of inertia (relative to center of mass)/(kg·m2)X3110
Wheelset yawing moment of inertia (relative to center of mass)/(kg·m2)X4800
Load-bearing saddle weight/(kg)X527
Load-bearing saddle rolling moment of inertia (relative to center of mass)/(kg·m2)X60.4
Load-bearing saddle pitching moment of inertia (relative to center of mass)/(kg·m2)X70.2
Load-bearing saddle yawing moment of inertia (relative to center of mass)/(kg·m2)X80.4
Longitudinal span of cross rod pin hole/(m)X91
Horizontal span of cross rod pin hole/(m)X101.981
Lateral span of resilient side bearing/(m)X111.52
Stop clearance/(mm)X1212
Primary suspension longitudinal stiffness/(MN·m−1)X1314
Primary suspension lateral stiffness/(MN·m−1)X1410
Primary suspension vertical stiffness/(MN·m−1)X15170
Secondary suspension longitudinal stiffness/(MN·m−1)X161.8
Secondary suspension lateral stiffness/(MN·m−1)X171.8
Secondary suspension lateral shock absorber damping/(MN·s·m−1)X1850
Swing arm node longitudinal/vertical stiffness/(MN·m−1)X1930,000
Primary spring longitudinal/lateral stiffness/(MN·m−1)X201000
Table 2. Suspension parameter design values.
Table 2. Suspension parameter design values.
Dynamical ParameterMinimumMaximum
X110.762.28
X12618
X13721
X14515
X1585255
X160.92.7
X170.92.7
X182575
X1915,00045,000
X205001500
Table 3. Middle stage of the algorithm.
Table 3. Middle stage of the algorithm.
n_genn_evaln_ndsepsIndicator
1111150500.0381746939ideal
1121160500.0006818878f
1131170500.0010485927f
1141180500.0024256293f
1151190500.0034794493f
1161200500.0016466931f
1171210500.0023378674f
1181220500.0073210258nadir
Table 4. Late stage of the algorithm.
Table 4. Late stage of the algorithm.
n_genn_evaln_ndsepsIndicator
4934970500.0028696928f
4944980500.0005592864f
4954990500.0018608608f
4965000500.0033501854f
4975010500.0003631807f
4985020500.0010969726f
4995030500.0016310799f
5005040500.0018601757f
Table 5. Key settings’ estimation outcome.
Table 5. Key settings’ estimation outcome.
Dynamic ParameterInitial ValueEstimated Value
X131416.1
X14108.3
X15170164
X161.81.7
X171.81.91
X185051.3
Table 6. Parameter settings of three typical working conditions.
Table 6. Parameter settings of three typical working conditions.
Working ConditionSpeedCurve RadiusSlope
Straight line60 km/h
Curved line60 km/h300 m
Long and steep uphill line60 km/h 0.1
Table 7. Relative error of wheel–rail forces by integrating various models and algorithms.
Table 7. Relative error of wheel–rail forces by integrating various models and algorithms.
Simulated Wheel–Rail Vertical Force/(kN)Predicted ValueRelative Error RateSimulated Wheel–Rail Lateral Force/(kN)Predicted ValueRelative Error Rate
RBF126.13123.861.80%20.322.3510.09%
CNN-LSTM126.13123.911.76%20.321.737.04%
CNN-BiLSTM126.13128.381.78%20.321.244.63%
BP126.13129.042.30%20.318.976.55%
CNN-GRU proposed in this paper126.13128.131.56%20.319.573.59%
Table 8. Comparison of simulated and real-world values of wheel–track interaction force before parameter correction.
Table 8. Comparison of simulated and real-world values of wheel–track interaction force before parameter correction.
Working ConditionSimulated Wheel–Rail Lateral Force/(kN)Measured Wheel–Track ForceError RateSimulated Wheel–Track Vertical Interaction Force/(kN)Measured Wheel–Track InteractionError Rate
Straight line12.4811.429.28%140.20138.910.93%
Curved line31.5229.676.24%131.28128.122.47%
Long and steep uphill line13.2411.2118.11%140.95138.172.01%
Table 9. Comparison of simulated and real-world values of wheel–track interaction force after parameter correction.
Table 9. Comparison of simulated and real-world values of wheel–track interaction force after parameter correction.
Working ConditionSimulated Wheel–Rail Lateral Force/(kN)Measured Wheel–Track ForceError RateSimulated Wheel–Track Vertical Interaction Force/(kN)Measured Wheel–Track InteractionError Rate
Straight line12.2211.427.00%140.54138.911.17%
Curved line31.0129.674.52%130.71128.122.02%
Long and steep uphill line12.3811.2110.44%139.34138.170.85%
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Zhang, C.; Wang, Y.; He, J. Suspension Parameter Estimation Method for Heavy-Duty Freight Trains Based on Deep Learning. Big Data Cogn. Comput. 2024, 8, 181. https://doi.org/10.3390/bdcc8120181

AMA Style

Zhang C, Wang Y, He J. Suspension Parameter Estimation Method for Heavy-Duty Freight Trains Based on Deep Learning. Big Data and Cognitive Computing. 2024; 8(12):181. https://doi.org/10.3390/bdcc8120181

Chicago/Turabian Style

Zhang, Changfan, Yuxuan Wang, and Jing He. 2024. "Suspension Parameter Estimation Method for Heavy-Duty Freight Trains Based on Deep Learning" Big Data and Cognitive Computing 8, no. 12: 181. https://doi.org/10.3390/bdcc8120181

APA Style

Zhang, C., Wang, Y., & He, J. (2024). Suspension Parameter Estimation Method for Heavy-Duty Freight Trains Based on Deep Learning. Big Data and Cognitive Computing, 8(12), 181. https://doi.org/10.3390/bdcc8120181

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