Temperature drift compensation of a FOG based on an HKSVM optimized by an improved hybrid BAS-GSA algorithm

Jianguo Liu; Xiyuan Chen

doi:10.1364/AO.440887

Applied Optics
Vol. 60,
Issue 34,
pp. 10539-10547
(2021)
•https://doi.org/10.1364/AO.440887

Temperature drift compensation of a FOG based on an HKSVM optimized by an improved hybrid BAS-GSA algorithm

Jianguo Liu and Xiyuan Chen

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Jianguo Liu and Xiyuan Chen, "Temperature drift compensation of a FOG based on an HKSVM optimized by an improved hybrid BAS-GSA algorithm," Appl. Opt. 60, 10539-10547 (2021)

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Abstract

In this paper, the optimal hybrid kernel support vector machine is employed to propose a compensation strategy intended for the temperature drift of a fiber optical gyroscope (FOG). First, the mode of the hybrid kernel with an interpolation and extrapolation capability is constructed, which consists of the radial basis function and the polynomial kernel function. Second, the combination model of the beetle antennae search algorithm and gravitational search algorithm that has both local and global search capability is proposed to optimize the structure-related parameters of a hybrid kernel support vector machine (HKSVM). Finally, the proposed approach is trained and tested using the experimental data of temperature drift at two different rates of temperature change (10°C/min and 5°C/min). In addition, the proposed method is validated against those conventional compensation algorithms. According to the research results, the compensation error (mean squared error) of the proposed approach is reduced by 92% compared to the traditional support vector machine based on the radial basis function.

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Data Availability

Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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	Initial Settings	Values’ Scope	Final Values
GRID-RBKFSVM	Step $s i z e = 1$ .	Scope of original values: $C \in [0.002, 32]$ , $δ \in [0.002, 32]$ , $d \in [1, 5]$ , $w \in [0, 1]$ .	$C = 2.8$ , $δ = 0.22$
GRID-PKFSVM	Step $s i z e = 1$ .		$C = 8$ , $d = 4.7$
GRID-HKSVM	Step $s i z e = 1$ .		$C = 16$ , $d = 2.45$ , $δ = 0.09$ , $w = 0.1$
GSA-HKSVM	$G_{0} = 10$ , $τ = 15$ , $φ = 0.1$ , $T_{max} = 100$ , $N = 20$ .		$C = 4.2$ , $d = 4.2$ , $δ = 0.07$ , $w = 0.81$
BAS-HKSVM	$d_{0} = 1.5$ , $μ_{0} = 1.0$ , $v = 0.95$ , $T_{max} = 100$ , $N = 20$ .	Scope of normalized values: $C, δ, d, w \in [- 9, 5]$ .	$C = 2.3$ , $d = 3.8$ , $δ = 0.1$ , $w = 0.78$
PSO-HKSVM	Maximum iterations: 100, Learning factor: 0.5, Number of beetles: 20		$C = 3.1$ , $d = 2 .3$ , $δ = 0.1 8$ , $w = 0. 21$
BAS-GSA-HKSVM	$d_{0} = 1.5$ , $μ_{0} = 1.0$ , $v = 0.95$ , $G_{0} = 10$ , $τ = 16$ , $φ = 0.1$ , $α = 0.5$ , $N = 20$ , $T_{max} = 100$ , ${f i t}_{min} = 0.0001$ .		$C = 1.7$ , $d = 3.8$ , $δ = 0.11$ , $w = 0.37$

		GRID-PKFSVM	GRID-RBKFSVM	GRID-HKSVM
Training data	MSE (°/h)	0.0126	0.004	0.00086
	SSE ( $(^{\circ} / h)^{2}$ )	54.59	17.21	3.2977
	AAE (°/h)	0.3112	0.1324	0.0588
	MAPE (°/h)	1.2874	0.7062	0.437
Testing data	MSE (°/h)	0.0029	0.0064	0.0015
	SSE ( $(^{\circ} / h)^{2}$ )	12.72	27.68	6.5
	AAE (°/h)	0.1791	0.2486	0.1217
	MAPE (°/h)	0.75	1.416	1.54

	GRID-HKSVM	GSA-HKSVM	BAS-HKSVM	PSO-HKSVM	BAS-GSA-HKSVM
MSE (°/h)	0.00086	0.00116	0.0012	0.0011	0.00047
SSE ( $(^{\circ} / h)^{2}$ )	3.2977	5.05	6.251	4.86	2.205
AAE (°/h)	0.0588	0.0681	0.0808	0.073	0.0521
MAPE (°/h)	0.437	0.3695	0.441	0.453	0.3738
Training time (s)	12000	600	989	590	1350

	GRID-HKSVM	GSA-HKSVM	BAS-HKSVM	PSO-HKSVM	BAS-GSA-HKSVM
MSE (°/h)	0.0015	0.0057	0.00075	0.002	0.00054
SSE ( $(^{\circ} / h)^{2}$ )	6.5	14.599	2.6045	9.05	2.3585
AAE (°/h)	0.1217	0.2217	0.0835	0.165	0.0766
MAPE (°/h)	1.54	2.1851	0.6728	1.31	0.6888

	GRID-HKSVM	GSA-HKSVM	BAS-HKSVM	PSO-HKSVM	BAS-GSA–HKSVM	Original Data
K ( $^{\circ} / h^{3 / 2}$ )	0.055	0.051	0.049	0.05	0.035	0.056
B (°/h)	0.104	0.127	0.1	0.12	0.049	0.16
N ( $^{\circ} / h^{1 / 2}$ )	0.0512	0.0369	0.04	0.041	0.0272	0.0524

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Applied Optics