4.1. Characteristics of the Azimuth Error Introduced by Stochastic Errors of Gyros

As mentioned above in Section 3, the phi-angle-based approach and the psi-angle-based approach are two equivalent approaches for derivation of error equations of an INS. The relationship between them is shown as follows (Goshen-Meskin, and Bar-Itzhack, Reference Goshen-Meskin and Bar-Itzhack1992):

(8)$${{\rm \bf \Phi} ^n} = \delta {\rm \bf \theta}^n + {\rm \bf \psi}^n$$

where Φ is the phi-angle error, and ψ is the psi-angle error. δ θ is the position error, which can be written as:

(9)$$\delta {{\rm \bf \theta} ^n} = {\left[ {\matrix{ {\delta {\theta _x}} & {\delta {\theta _y}} & {\delta {\theta _z}} \cr}} \right]^{\rm T}} = {\left[ {\matrix{ { - \delta L} & {\delta \lambda \cos L} & {\delta \lambda \sin L} \cr}} \right]^{\rm T}}$$

where L represents a local latitude, δL and δλ represent a latitude error and a longitude error, respectively.

With calibration, the characteristics of deterministic errors, such as the g-dependent biases, the scale factor errors and the misalignment errors, can be well investigated (Syed et al., Reference Syed, Aggarwal, Goodall, Niu and El-Sheimy2007; Nieminen et al., Reference Nieminen, Kangas, Suuriniemi and Kettunen2010; Fong et al., Reference Fong, Ong and Nee2008; Zhang et al., Reference Zhang, Wu, Wu, Wu and Hu2010; Li et al., Reference Li, Niu, Zhang, Zhang and Shi2012). The sensor error model can be simplified as follows:

(10)$${\rm \bf \varepsilon}^b = {\rm \bf b}_g + {\rm \bf v}_g$$

(11)$${\nabla ^b} = {{\rm \bf b}_a} + {{\rm \bf \nu} _a}$$

According to the principles of the dual-axis rotational INS (Levinson and Majure, Reference Levinson and Majure1987; Yuan et al., Reference Yuan, Liao and Han2012), the items b_g and b_a in Equations (4) and (5) can be averaged out, thus the stochastic error introduced by the gyros is the main error source in the dual-axis rotational INS. Thus, Equation (1) can be rewritten as follows:

(12)$${\dot {\bf \rm \psi} ^n} + {\rm \bf \omega} _{in}^n \times {{\rm \bf \psi} ^n} = {{\rm \bf \nu} _g}$$

For applications to a land vehicle, a ship or a submarine, which lasts for a long term, typically for several days, velocity damping is usually utilised to reduce navigation errors which propagate in a Schuler period, and hence the pitch error and the roll error are greatly attenuated (Gao, Reference Gao2012). However, the velocity damping is not effective in reducing the azimuth error.

4.2. The TPR method

To estimate and correct the azimuth error and the position error introduced by the stochastic errors, we propose an optimised position-fix reset method called Twice Position-fix Reset (TPR). It contains two steps:

1. a) Reset the position of the INS when first position information is available;

2. b) Estimate and correct the azimuth error and reset the position of the INS when second position information is available. The following are the details of the TPR method.

Considering ω_ieⁿ >> ω_enⁿ for low speed vehicles, the psi-angle-based equation in a dual-axis rotational INS can be simplified as:

(13)$${\dot {\bf \rm \psi} ^n} + {\rm \bf \omega} _{ie}^n \times {{\rm \bf \psi} ^n} = {{\rm \bf \nu} _g}$$

where ω_ieⁿ = [0 Ωcos L Ωsin L]^T, Ω is the Earth's rate. From Equation (13), the characteristic period of psi-angle is:

(14)$${T_0} = \displaystyle{{2\pi} \over {\left\vert {\omega _{ie}^n} \right\vert}} = \displaystyle{{2\pi} \over \Omega} $$

In general, the stochastic errors of gyros slowly and accumulatively affect the propagation characteristic of the psi-angle in the characteristic period (T ₀ = 24 hours), so the stochastic errors of the gyros need to be compensated in a long-term mission. A general azimuth error of the psi-angle propagates as shown in Figure 4.

Figure 4. Propagation characteristic of an azimuth error of the psi-angle.

The interval between the two resets is about 4–6 hours, which is much shorter than the characteristic period. As shown in Figure 4, within the initial 4–6 hours, the accumulated effect caused by the stochastic error is still limited. Therefore, within the interval between the two resets, the psi-angle with stochastic errors may be fitted by the psi-angle without considering the stochastic errors.

For example, a reset is performed at the 40^th hour, and the fitting is performed between the 40^th hour and the 46^th hour. As shown in Figure 5, the curve of an azimuth error with a stochastic error is fit with the curve of the azimuth error without considering the stochastic error. The fitting is accurate enough for the short interval.

Figure 5. Fitting an azimuth error by ignoring the stochastic error between the 40^th hour and the 46^th hour.

According to Equation (14) for the psi-angle with the stochastic errors, Equation (15) is obtained for the psi-angle without considering the stochastic error, which can be written as follows:

(15)$${\dot {\bf \rm \psi} ^n} + {\rm \bf \omega} _{ie}^n \times {{\rm \bf \psi} ^n} = 0$$

Because the latitude varies as vehicle moves, the ω_ieⁿ is not constant. To solve Equation (15), a right-handed frame called s-frame is defined. The s-frame has its origin at the location of the navigation system, and its x-axis and y-axis align with the directions of east and the Earth axis. The s-frame can be obtained by rotating the navigation frame by an angle (Latitude) about the x-axes. Figure 6 shows the relationship between the s-frame and the navigation frame.

Figure 6. The s-frame and the navigation frame.

The DCM of the navigation frame with respect to the s-frame is:

(16)$${\rm \bf C}_n^s = \left[ {\matrix{ 1 & 0 & 0 \cr 0 & {\cos L} & {\sin L} \cr 0 & { - \sin L} & {\cos L} \cr}} \right]$$

According to the DCM C_n^s, the psi-angle in the s-frame can be written as:

(17)$${{\rm \bf \psi} ^s} = {\rm \bf C}_n^s {{\rm \bf \psi} ^n}$$

Since s-frame is stationary respect to the n-frame, ω_ns^s = 0. Substituting ψⁿ in Equation (15) with ψ^s, the psi-angle-based equation in the s-frame gives:

(18)$$\left\{ {\matrix{ {\dot {\rm \psi} _x^s + \Omega \cdot {\rm \psi} _z^s = 0} \cr {\dot {\rm \psi} _y^s = 0} \cr {\dot {\rm \psi} _z^s - \Omega \cdot {\rm \psi} _x^s = 0} \cr}} \right.$$

The analytical solutions of Equation (18) are given by:

(19)$${{\rm \bf \psi} ^s}(t) = {\rm \bf T}(t \comma {t_0}) \cdot {{\rm \bf \psi} ^s}({t_0})$$

With

(20)$${\rm \bf T}(t \comma {t_0}) = \left[ {\matrix{ {\cos \Omega (t - {t_0})} & 0 & { - \sin \Omega (t - {t_0})} \cr 0 & 1 & 0 \cr {\sin \Omega (t - {t_0})} & 0 & {\cos \Omega (t - {t_0})} \cr}} \right]$$

According to the analysis in Subsection 4.1, the pitch error and the roll error can be greatly reduced by velocity damping, thus, it is sufficiently precise to assume the pitch error and the roll error are zero during a period of the two observations. Thus, Equation (8) can be written as:

(21)$$\left\{ {\matrix{ {{\rm \phi} _x^n = {\delta} \theta _x^n + {\rm \psi} _x^n = 0} \cr {{\rm \phi} _y^n = {\delta} \theta _y^n + {\rm \psi} _y^n = 0} \cr {{\rm \phi} _z^n = {\delta} \theta _z^n + {\rm \psi} _z^n} \cr}} \right.$$

Substituting Equations (8), (9), and (18) into Equations (21) yields:

(22)$$\left[ {\matrix{ {{\delta} L} \cr {{\delta} \lambda} \cr {{\rm \phi} _z^n} \cr}} \right] = \left[ {\matrix{ 1 & 0 & 0 \cr 0 & { - 1} & {\tan L} \cr 0 & 0 & {\sec L} \cr}} \right]\left[ {\matrix{ {{\rm \psi} _x^s} \cr {{\rm \psi} _y^s} \cr {{\rm \psi} _z^s} \cr}} \right]$$

By the first position information, Equation (19) can be rearranged as a first position-fix reset equation:

(23)$$\left[ {\matrix{ {{\delta} L({t_1})} \cr {{\delta} \lambda ({t_1})} \cr {{\rm \phi} _z^n ({t_1})} \cr}} \right] = \left[ {\matrix{ 1 & 0 & 0 \cr 0 & { - 1} & {\tan L} \cr 0 & 0 & {\sec L} \cr}} \right]\left[ {\matrix{ {{\rm \psi} _x^s ({t_1})} \cr {{\rm \psi} _y^s ({t_1})} \cr {{\rm \psi} _z^s ({t_1})} \cr}} \right]$$

Similarly, a second position-fix reset equation is given by:

(24)$$\left[ {\matrix{ {{\delta} L({t_2})} \cr {{\delta} \lambda ({t_2})} \cr {{\rm \phi} _z^n ({t_2})} \cr}} \right] = \left[ {\matrix{ 1 & 0 & 0 \cr 0 & { - 1} & {\tan L} \cr 0 & 0 & {\sec L} \cr}} \right]\left[ {\matrix{ {{\rm \psi} _x^s ({t_2})} \cr {{\rm \psi} _y^s ({t_2})} \cr {{\rm \psi} _z^s ({t_2})} \cr}} \right]$$

Following Equations (23) and (24), the relationship between the two observations can be written as:

(25)$$\left\{ {\matrix{ {{\rm \psi} _x^s ({t_2}) = \cos \Omega ({t_2} - {t_1}) \cdot {\rm \psi} _x^s ({t_1}) - \sin \Omega ({t_2} - {t_1}) \cdot {\rm \psi} _z^s ({t_1})} \cr {{\rm \psi} _z^s ({t_2}) = \sin \Omega ({t_2} - {t_1}) \cdot {\rm \psi} _x^s ({t_1}) + \cos \Omega ({t_2} - {t_1}) \cdot {\rm \psi} _z^s ({t_1})} \cr}} \right.$$

With the second position information, the item of ψ_x^s(t ₂) in Equation (24) can be calculated, and the items of ψ_z^s(t ₁) and ψ_z^s(t ₂) can be given by Equation (25). Substituting ψ _z^s(t ₂) in Equation (24), we can get the azimuth error ϕ_zⁿ(t ₂).

As stated above, there are three assumptions: a) pitch error and roll error are zero; b) the constant bias errors of gyros are averaged out; c) ω_ieⁿ >> ω_enⁿ. In practice, the assumptions are not satisfied all over the period of position-fix reset, but the TPR method is fine to estimate most parts of the azimuth error for applications with low speed and low manoeuvres, which was verified by simulations (Section 4.3) and field tests (Section 5).

4.3. Simulation of the TPR Method

To verify the advantage of the proposed TPR method, the conventional position-fix reset method and TPR method are both simulated. A stationary simulation is carried out with the following conditions: (1) an initial alignment attitude error is (0′, 0′, 1′), (2) the stochastic error of the gyro is 3 × 10⁻³ deg h^−1/2, the stochastic error of the accelerometer is 20 µg Hz^−1/2, and (3) the twice position-fix resets are carried out at the 17^th hour and the 21^th hour, respectively, (4) the INS navigates with velocity damping.

Figure 7 shows a comparison of azimuth errors with velocity damping by using the TPR method and by using the conventional position-fix reset method. A comparison of position outputs by using the TPR method and by using the conventional method is shown in Figure 8. Both methods corrected the position error at the 17^th hour. At the 21^th hour, the azimuth error (phi-angle error) which include the psi-angle error and the position error are compensated by the TPR method, while only the position error is compensated by the conventional position-fix reset method.

Figure 7. Azimuth errors (phi-angle) with velocity damping by using the TPR method and by using the conventional method.

Figure 8. Position outputs with velocity damping by using the TPR method and by using the conventional method.

Radial-position errors compensated by the TPR method and by the conventional position-fix reset method are compared in Figure 9. It can be seen that the radial-position error is less than 100 m by using the TPR method, while it is more than 310 m by using the conventional method.

Figure 9. Radial-position errors with velocity damping by using the TPR method and by using the conventional method.

From the comparisons above, both the azimuth error and the radial-position error are significantly better corrected by the TPR method than by a conventional position-fix reset method under same conditions in simulations.