Lane Level Positioning Method for Unmanned Driving Based on Inertial System and Vector Map Information Fusion Applicable to GNSS Denied Environments
Abstract
:1. Introduction
- (1)
- An integrated positioning method based on inertial technology and vector map information fusion is proposed, which is applicable for GNSS denied environments such as underground parking lots and large logistics complex areas;
- (2)
- The matching strategies are established, and the inertial positioning error model is used as a basis to select candidate road segments;
- (3)
- Validation experiments have been conducted out in an underground parking lot, and the results show that the positioning error for driving 5 km has been reduced from the meter level to within 30 cm.
2. Definition of the Coordinate System
3. Overall Design of the Lane Level Positioning Method
4. Dead Reckoning Principle Based on Optical Fiber IMU/Odometer
5. Map Matching Model Based on HMM
5.1. Selection of Candidate Road Segments
5.2. Initial Distribution Probability
5.3. Transition Probability
5.4. Observation Probability
6. Optimal Path Selection Based on Viterbi Algorithm
Algorithm 1: Viterbi Algorithm | |
Input: Collection of candidate road segments , | |
Sampled points set | |
Output: Optimal Segment Sequence | |
1: | Let P denote the highest score; |
2: | Let Q [ ] denote the set of the optimal segments; |
3: | |
4: | Set i |
5: | for to do |
6: | |
7: | |
8: | Q = Q + ; |
9: | end for |
10: | for to do |
11: | for to do |
12: | |
13: | |
14: | Q = Q + |
15: | end for |
16: | end for |
17: | return |
7. Evaluation Method
8. Experiment and Discussion
- Case 1:
- The vehicle starts from the northeast corner of the map and drives along the lane line to the southwest corner of the map. The vehicle drives eight laps in the underground garage. The red line in Figure 10 represents the track of the vehicle. A curve is selected in the lower right corner of Figure 10 and enlarged locally for better visualization.
- Case 2:
- The vehicle drives one lap in the underground garage. There are more curves and more complicated road conditions.
9. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Method | Typical Work | Advantage | Disadvantage |
---|---|---|---|
SINS/OD | [7] | 1. High autonomy; 2. Low cost; | 1. Error accumulation exists; |
SINS/Altimeter | [8] | 1. Able to suppress divergence of altitude channel; 2. Low cost; | 1. Low accuracy; |
SINS/GMNS | [9,10] | 1. No accumulated error; 2. Work all-weather; | 1. Vulnerable to interference; 2. Low reliability; |
SINS + SMNS | [11,12] | 1. Low cost; 2. No accumulated error. | 1. Difficulty in database collection; 2. Vulnerable to weather. |
Specific Algorithm | Typical Work | Type | Information Source | Positioning Accuracy |
---|---|---|---|---|
Line to line | [24] | Geometry-based | GPS | 5.5 m (80%) |
Enhanced probability statistics | [29] | Probability statistics-based | GPS | —— (85%) |
Weighted topology matching | [33] | Road topology-based | GPS | 2.82 m (84%) |
HMM | [38] | Integrated map matching | GPS | 1.3 m (98%) |
Device | Parameter | Value |
---|---|---|
Fiber optic gyroscope | Range | ±400°/s |
Bias stability | ≤0.1°/h (1 ) | |
Bias repeatability | ≤0.1°/h (1 ) | |
Random walk coefficient | ≤0.02°/√h | |
Scale factor nonlinearity | ≤100 ppm | |
Scale factor repeatability | ≤100 ppm | |
Bandwidth | ≥200 Hz | |
Accelerometer | Range | ±20 g |
Bias stability | ≤0.2 mg (1 ) | |
Bias repeatability | ≤0.2 mg (1 ) | |
Random walk coefficient | ≤100 ppm | |
Scale factor nonlinearity | ≤100 ppm | |
Scale factor repeatability | ≥200 Hz |
Trajectory | Number of Sampled Points | Real Driving Distance (m) | The Radius of the Positioning Circle (m) | Number of Candidate Segments |
---|---|---|---|---|
S1 | 1457 | 420 | 5 | 67 |
S2 | 1368 | 420 | 10 | 78 |
S3 | 2230 | 550 | 5 | 71 |
Trajectory | Average Length of Candidate Segments (m) | Average Distance between Adjacent Sampled Points (cm) |
---|---|---|
S1 | 27.0 | 30.8 |
S2 | 30.2 | 49.8 |
S3 | 27.7 | 26.3 |
Trajectory | Recall | CMP | PE before Matching (m) | PE after Matching (m) | Time of Running (s) |
---|---|---|---|---|---|
S1 | 100% | 100% | 0.59 | 0.12 | 29.38 |
S2 | 94.4% | 98.57% | 1.03 | 0.24 | 20.18 |
S3 | 100% | 99.1% | 0.84 | 0.18 | 47.43 |
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Dai, M.; Li, H.; Liang, J.; Zhang, C.; Pan, X.; Tian, Y.; Cao, J.; Wang, Y. Lane Level Positioning Method for Unmanned Driving Based on Inertial System and Vector Map Information Fusion Applicable to GNSS Denied Environments. Drones 2023, 7, 239. https://doi.org/10.3390/drones7040239
Dai M, Li H, Liang J, Zhang C, Pan X, Tian Y, Cao J, Wang Y. Lane Level Positioning Method for Unmanned Driving Based on Inertial System and Vector Map Information Fusion Applicable to GNSS Denied Environments. Drones. 2023; 7(4):239. https://doi.org/10.3390/drones7040239
Chicago/Turabian StyleDai, Minpeng, Haoyang Li, Jian Liang, Chunxi Zhang, Xiong Pan, Yizhuo Tian, Jinguo Cao, and Yuxuan Wang. 2023. "Lane Level Positioning Method for Unmanned Driving Based on Inertial System and Vector Map Information Fusion Applicable to GNSS Denied Environments" Drones 7, no. 4: 239. https://doi.org/10.3390/drones7040239
APA StyleDai, M., Li, H., Liang, J., Zhang, C., Pan, X., Tian, Y., Cao, J., & Wang, Y. (2023). Lane Level Positioning Method for Unmanned Driving Based on Inertial System and Vector Map Information Fusion Applicable to GNSS Denied Environments. Drones, 7(4), 239. https://doi.org/10.3390/drones7040239