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面向自动驾驶的跨视图定位技术综述

段星宇 吴涛 李峻翔 王耀南 刘流

段星宇, 吴涛, 李峻翔, 王耀南, 刘流. 面向自动驾驶的跨视图定位技术综述. 自动化学报, xxxx, xx(x): x−xx doi: 10.16383/j.aas.c250243
引用本文: 段星宇, 吴涛, 李峻翔, 王耀南, 刘流. 面向自动驾驶的跨视图定位技术综述. 自动化学报, xxxx, xx(x): x−xx doi: 10.16383/j.aas.c250243
Duan Xing-Yu, Wu Tao, Li Jun-Xiang, Wang Yao-Nan, Liu Liu. A review of cross-view localization techniques for autonomous driving. Acta Automatica Sinica, xxxx, xx(x): x−xx doi: 10.16383/j.aas.c250243
Citation: Duan Xing-Yu, Wu Tao, Li Jun-Xiang, Wang Yao-Nan, Liu Liu. A review of cross-view localization techniques for autonomous driving. Acta Automatica Sinica, xxxx, xx(x): x−xx doi: 10.16383/j.aas.c250243

面向自动驾驶的跨视图定位技术综述

doi: 10.16383/j.aas.c250243 cstr: 32138.14.j.aas.c250243
基金项目: 湖南省自然科学基金(2026JJ40065)资助
详细信息
    作者简介:

    段星宇:国防科技大学智能科学学院博士研究生. 2023年获得国防科技大学学士学位. 主要研究方向为智能驾驶技术. E-mail: duanxingyu19@nudt.edu.cn

    吴涛:国防科技大学智能科学学院研究员. 2002年获得国防科技大学博士学位. 主要研究方向为自动驾驶, 感知规划.本文通信作者. E-mail: wutao@nudt.edu.cn

    李峻翔:国防科技大学智能科学学院副研究员. 2019年获得国防科技大学博士学位. 主要研究方向为无人车规划与感知. E-mail: lijunxiang15@nudt.edu.cn

    王耀南:中国工程院院士, 湖南大学人工智能与机器人学院教授. 1995年获得湖南大学博士学位. 主要研究方向为机器人学, 智能控制和图像处理. E-mail: yaonan@hnu.edu.cn

    刘流:国防科技大学智能科学学院副工程师. 2013年获得北京航空航天大学硕士学位. 主要研究方向为无人车决策控制与测试. E-mail: lijunxiang15@nudt.edu.cn

A Review of Cross-view Localization Techniques for Autonomous Driving

Funds: Supported by Natural Science Foundation of Hunan Province (2026JJ40065)
More Information
    Author Bio:

    DUAN Xing-Yu Ph.D. candidate at the College of Intelligence Science and Technology, National University of Defense Technology. He received his bachelor degree from National University of Defense Technology in 2023. His main research interest is intelligent driving technology

    WU Tao Researcher at the College of Intelligence Science and Technology, National University of Defense Technology. He received his Ph.D. degree from National University of Defense Technology in 2002. His research interests include autonomous driving and perception and planning. Corresponding author of this paper

    LI Jun-Xiang Associate researcher at the College of Intelligence Science and Technology, National University of Defense Technology. He received his Ph.D. degree from National University of Defense Technology in 2019. His research interests include unmanned ground vehicle planning and perception

    WANG Yao-Nan Academician at Chinese Academy of Engineering, professor at the School of Artificial Intelligence and Robotics, Hunan University. He received his Ph.D. degree from Hunan University in 1995. His research interests include robotics, intelligent control, and image processing

    Liu Liu Associate engineer at the College of Intelligence Science and Technology, National University of Defense Technology. He received his master degree from Beihang University in 2013. His research interests include unmanned ground vehicle decision control and testing

  • 摘要: 跨视图定位技术正经历从通用框架向面向自动驾驶的专有化架构深刻转变. 为系统梳理这一领域, 首先回顾其从粗略检索到精准3-DoF姿态估计的发展脉络. 进而, 提出一个从“输入数据、模型架构、评价指标、损失函数”四个核心维度出发的分析框架, 以此对主流方法进行系统性解构与归因, 揭示不同技术路径的设计权衡. 此外, 详细评述自动驾驶跨视图定位数据集, 并指出当前评估在泛化能力考量上的不足; 为此, 构建新的包含结构化道路与越野场景的CSC-Shanmao数据集, 作为评估模型环境适应性的新基准, 并在其上验证了多种代表性方法, 结果表明面向自动驾驶设计的方法在精度与鲁棒性上优势显著, 但同时也暴露出精度、效率与泛化性之间的突出矛盾. 最后, 总结该技术在轻量化部署、多模态融合可靠性及评估体系等方面面临的严峻挑战, 并展望轻量化设计、可信评估基准及主动感知等未来关键研究方向.
  • 图  1  本文贡献总览

    Fig.  1  Overview of contributions in this paper

    图  2  面向自动驾驶的跨视图定位方法的发展历程

    Fig.  2  Evolution of cross-view localization methods for autonomous driving

    图  3  面向自动驾驶的跨视图定位方法一览

    Fig.  3  Overview of cross-view localization methods for autonomous driving

    图  4  基于KITTI-CVL数据集的同区域测试

    Fig.  4  Same-region testing based on the KITTI-CVL dataset

    图  5  基于KITTI-CVL数据集的跨区域测试

    Fig.  5  Cross-region testing based on the KITTI-CVL dataset

    图  6  面向自动驾驶的跨视图定位方法性能对比

    Fig.  6  Performance comparison of cross-view localization methods for autonomous driving

    图  7  跨视图定位方法未来研究方向

    Fig.  7  Future research directions of cross-view localization methods

    表  1  CVUSA数据集上的跨视图定位方法性能对比

    Table  1  Performance comparison of cross-view localization methods on the CVUSA dataset

    方法名称 r@1 r@5 r@10 r@1(%)
    CVM-NET[8] 22.47 49.98 63.18 93.62
    文献[51]中的方法 40.79 66.82 76.36 96.12
    DSM[55] 91.96 97.50 98.54 99.67
    Accurate3-DoF[62] 92.69 97.78 98.60 99.61
    HADGEO[79] 95.01 98.45 99.10
    GeoSSK[89] 94.13 98.75 99.27 99.85
    DSTG[90] 95.22 98.66 99.13 99.79
    下载: 导出CSV

    表  2  CVACTval数据集上的跨视图定位方法性能对比

    Table  2  Performance comparison of cross-view localization methods on the CVACTval dataset

    方法名称 r@1 r@5 r@10 r@1(%)
    CVM-NET[8] 20.15 45.00 56.87 87.57
    文献[51]中的方法 46.96 68.28 75.48 92.01
    DSM[55] 82.49 92.44 93.99 97.32
    Accurate3-DoF[62] 82.70 92.50 94.24 97.65
    HADGEO[79] 86.48 94.21 95.50
    GeoSSK[89] 85.56 94.93 96.17 98.54
    DSTG[90] 86.29 95.43 96.85 98.81
    下载: 导出CSV

    表  3  KITTI-CVL数据集上不同实验条件下的跨视图定位方法性能对比

    Table  3  Performance comparison of cross-view localization methods under different experimental settings on the KITTI-CVL dataset

    方法 定位$\downarrow$(m) 横向$\uparrow$(%) 纵向$\uparrow$(%) 方向$\uparrow$(%) 方向$\downarrow$($^\circ$)
    平均 中位 0.25 m 0.5 m 1 m 3 m 中位$\downarrow$ 0.25 m 0.5 m 1 m 3 m 中位$\downarrow$ 1$^\circ$ 2$^\circ$ 3$^\circ$ 4$^\circ$ 5$^\circ$ 平均 中位
    方向先验噪声为± 15°, 横/纵位置先验噪声为± 5m
    SIBCL[52]25.5946.2672.630.5421.9141.2264.470.6456.0579.7090.890.85
    DSM[55]8.5113.9723.443.487.6711.0220.034.973.138.2917.4412.73
    CVML[58]6.1112.2423.782.405.9711.6823.732.46
    LM[60]16.5132.0557.650.837.1414.1127.412.0129.8353.4176.513.23
    PureACL[64]84.5899.5499.980.1298.55100.00100.000.0931.1854.1376.003.571.78
    方向先验噪声为± 10°, 横/纵位置先验噪声为± 20 m(同区域测试)
    DSM[55]10.1230.674.0812.013.5813.8124.44
    HC-Net[59]0.800.5099.0192.2091.3599.840.450.33
    LM[60]12.0811.4235.5470.775.2215.8819.6451.7671.723.722.83
    BoostAcc[63]10.015.1976.4496.3423.5450.5799.10100.00100.000.550.42
    PureACL[64]2.420.4291.9593.4091.8692.1232.1753.8971.663.971.77
    SliceMatch[65]7.964.3949.0915.1913.4164.174.123.65
    文献[66]中的方法1.480.4795.4787.8989.4099.310.490.30
    CCVPE[67]1.220.6297.3598.6577.1396.0877.3999.4799.950.670.54
    T2GA[68]0.200.1799.9799.9799.9799.9750.9583.9795.451.530.93
    C2F-CCPE[78]0.920.4498.5299.0288.9796.7799.9799.99100.000.010.01
    FG2[88]0.750.5299.7386.9961.1795.651.280.74
    CVLGSA[91]1.150.3598.2299.0492.4796.1399.86100.00100.000.280.23
    CPC-CVPE[93]1.030.5597.8786.2186.2197.981.010.65
    方向先验噪声为± 10°, 横/纵位置先验噪声为± 20 m(跨区域测试)
    DSM[55]10.7731.373.8711.733.5314.0923.95
    HC-Net[59]8.474.5775.0058.9333.5883.783.221.63
    LM[60]12.5812.1127.8259.795.7516.3618.4249.7271.003.953.03
    BoostAcc[63]13.019.0657.7286.7714.1534.5998.98100.00100.000.560.43
    PureACL[64]6.200.6167.2487.2664.8173.6323.4548.6959.244.262.48
    SliceMatch[65]13.509.7732.438.3046.8246.824.206.61
    文献[66]中的方法7.973.5254.1923.1043.4489.312.171.21
    CCVPE[67]9.163.3344.0681.7223.0852.8557.7292.3496.191.550.84
    T2GA[68]0.210.1899.9299.9699.9199.9138.3180.1292.482.041.38
    C2F-CCPE[78]8.163.1449.5587.3920.9655.2098.8598.9899.020.260.01
    FG2[88]7.454.0389.4612.4230.3481.173.331.88
    CVLGSA[91]9.504.3460.0091.2421.3644.6899.53100.00100.000.310.24
    方向先验噪声为± 45°, 横/纵位置先验噪声为± 20 m(同区域测试)
    SIBCL[52]17.0133.3461.880.7020.6831.4055.580.8635.5055.0471.068.901.69
    BoostAcc[63]21.9241.5167.720.635.179.3816.545.4218.4535.2562.203.882.98
    PureACL[64]58.7566.3470.600.2345.6568.2374.870.3737.9952.5764.138.132.80
    CCVPE[67]11.0522.0542.091.227.4513.3624.973.3534.6660.7284.033.431.53
    T2GA[68]76.2097.7399.970.1498.1899.8999.970.0748.9766.2990.542.191.07
    方向先验噪声为± 45°, 横/纵位置先验噪声为± 20 m(跨区域测试)
    SIBCL[52]16.9032.6258.240.7119.5830.7449.251.0525.0250.1860.169.671.96
    BoostAcc[63]14.8829.2052.640.933.385.5611.738.9212.4624.8747.265.614.26
    PureACL[64]50.2562.6364.560.257.4162.0464.230.4419.9536.2556.4910.963.16
    CCVPE[67]4.9610.0538.122.793.136.1412.458.163.3810.2417.4119.4615.39
    T2GA[68]75.9697.4799.970.1597.4999.8799.970.0736.1063.0886.182.881.44
    下载: 导出CSV

    表  4  面向自动驾驶的跨视图定位方法分类(依据评价指标)

    Table  4  Taxonomy of cross-view localization methods for autonomous driving based on evaluation metrics

    模型评价指标方法时间及论文来源输入创新点
    Top-K召回率DSM[55]2020 CVPR地面+鸟瞰/卫星极坐标变换对齐航拍图像与地面图像, 两流卷积网络学习深度特征
    CVLNet[61]2022 ACCV地面+鸟瞰/卫星通过几何驱动模块和场景先验匹配机制确定车载相机相对于卫星图中心的位置
    Accurate3-DoF[62]2022 TPAMI地面+鸟瞰/卫星设计双孪生网络结构, 提出两阶段定位机制, 使网络聚焦特定区域
    HADGEO[79]2024 ICASSP地面+鸟瞰/卫星设计新的损失函数, 结合全可学习卷积网络(ALFCN)提取特征
    GeoSSK[89]2025 MMM地面+鸟瞰/卫星设计基于交叉注意力的跨融合交互模块(CIM)和语义相似性知识蒸馏(SSKD)
    DSTG[90]2025 TGRS地面+鸟瞰/卫星提出一种在不同分辨率级别之间进行教师模型与学生模型特征对齐的方法
    定位与方向估计的误差及召回率SIBCL[52]2023 ICRA地面+点云+卫星用地面图像和点云估计车辆的3-DoF姿态
    MapLocNet[53]2024 IROS地面+鸟瞰/卫星使用从粗到精的特征注册策略进行视觉重定位
    AutoVision[54]2019 ICRA地面+鸟瞰/卫星用粒子滤波方法结合CVM-Net进行跨视图匹配
    SLAM-G2S-Fusion[57]2024 ICRA地面+鸟瞰/卫星将vSLAM与G2S方法结合形成一种从粗到细的选择方法
    CVML[58]2022 ECCV地面+鸟瞰/卫星利用密集的卫星描述符和相似性匹配来生成密集概率分布
    HC-Net[59]2023 NeurIPS地面+鸟瞰/卫星提出单应性估计模块消除重复采样并忽略不可观察内容
    LM[60]2022 CVPR地面+鸟瞰/卫星通过几何投影模块, 将卫星图像的深度特征投影到地面视角下, 再利用LM模块细化相机的姿态估计
    BoostAcc[63]2023 ICCV地面+鸟瞰/卫星提出几何引导交叉视图变换器, 解决了对象模糊和相机倾斜的问题
    PureACL[64]2023 ICCV地面+鸟瞰/卫星检测一致性关键点以及深度特征, 减少纯视觉匹配的模糊性
    SliceMatch[65]2023 CVPR地面+鸟瞰/卫星将水平视场分割成多个切片, 学习与定位和方向估计相关的特征
    文献[66]中的方法2023 NeurIPS地面+鸟瞰/卫星通过密集像素级流场来估计车载相机的3-DoF姿态
    CCVPE[67]2023 TU Delft地面+鸟瞰/卫星构建方向感知的图像描述符, 实现位置和方向的联合估计
    T2GA[68]2022 CVPR地面+鸟瞰/卫星T2GA模块整合离地特征, CycDA损失确保特征一致性, 等距投影损失(ERP)平衡关键点影响
    BEVRender[70]2024 IROS地面+鸟瞰/卫星生成局部鸟瞰图图像并将其与航拍视图对齐
    Geo-tracking[71]2022 IROS地面+点云+卫星将车载摄像头和激光雷达数据与地理配准的正射影像对齐
    文献[74]中的方法2024 JSTARS点云+ 卫星引入道路结构作为不同模态之间的桥梁
    AGL-NET[75]2024 IROS点云+卫星利用尺度分类器和特征差值方法处理尺度差异
    C2F-CCPE[78]2024 ICME地面+鸟瞰/卫星通过多尺度特征融合模块(LOFFM) 同时进行方向和位置的精确预测
    FG2[88]2025 CVPR地面+鸟瞰/卫星利用几何感知注意力与高度选择机制实现细粒度特征匹配
    CVLGSA[91]2025 IROS地面+鸟瞰/卫星通过视角驱动的注意力融合模块和投影稳定补丁引导优化器
    CPC-CVPE[93]2025 Sci. Data地面+点云+卫星通过多传感器融合实现精确的GNSS独立定位
    其他OrienterNet[76]2023 CVPR地面+ 卫星用卷积神经网络提取图像语义特征并将其提升为鸟瞰图表示, 同时将开放街图编码为神经地图
    下载: 导出CSV

    表  5  传统跨视图定位数据集

    Table  5  Traditional cross-view localization dataset

    数据集 发布时间 图像分辨率 图像类型 数据量 地点
    CVUSA[2] 2015 1232 × 224 (地面),
    750 × 750 (卫星)
    地面图像和卫星图像 44416对地面和卫星图像 美国
    San Francisco[57] 2015 256 × 256 地面图像和卫星图像 278561幅地面图像和
    174217幅卫星图像
    旧金山弗朗西斯科
    CVACT[51] 2019 多尺寸 地面图像和卫星图像 44416对地面和卫星图像以及
    92802幅额外测试图像
    澳大利亚堪培拉
    University-1652[10] 2020 512 × 512 地面图像、无人机图像和卫星图像 1652组地面、无人机和卫星图像 世界各地72所大学
    VIGOR[14] 2021 2048 × 1024 (地面),
    640 × 640 (卫星)
    地面图像和卫星图像 238696幅地面图像和
    90618幅卫星图像
    纽约市、旧金山弗朗西斯科、
    芝加哥和西雅图
    SUES-200[83] 2023 1080 × 1080 (无人机),
    512 × 512 (卫星)
    无人机图像和卫星图像 24120对无人机和卫星图像 上海工程科技大学周围
    下载: 导出CSV

    表  6  面向自动驾驶的跨视图定位数据集

    Table  6  Cross-view localization datasets for autonomous driving

    数据集 发布时间 图像分辨率 图像类型 数据量 地点
    KITTI-CVL[52] 2023 1242 × 375(地面),
    1280 × 1280(卫星)
    地面图像和卫星图像 30973幅地面视角图像和
    2750幅卫星图像
    德国卡尔斯鲁厄市
    FordAV-CVL[52] 2023 1656 × 860(地面),
    1280 × 1280(卫星)
    地面图像和卫星图像 30209对地面视角和
    卫星图像
    美国密歇根州
    Oxford RobotCar(+)[57] 2022 1280 × 960(地面),
    600 × 600(卫星)
    地面图像和卫星图像 24000对地面视角和
    卫星图像
    英国牛津
    KITTI(+)[60] 2023 1242 × 375(地面),
    1280 × 1280(卫星)
    地面图像和卫星图像 30973幅地面视角图像和
    2750幅卫星图像
    德国卡尔斯鲁厄市
    Ford Multi-AV[60] 2023 1656 × 860 (地面),
    1280 × 1280(卫星)
    地面图像和卫星图像 30209对地面视角和
    卫星图像
    美国密歇根州
    CSC-Shanmao
    (本文数据集)
    2025 960 × 540(地面),
    1280 × 1280(卫星)
    地面图像和卫星图像 24115对地面视角和
    卫星图像
    中国湖南省长沙市以及
    内蒙古包头市
    下载: 导出CSV

    表  7  现有先进方法在CSC-Shanmao数据集上的性能评测

    Table  7  Benchmarking state-of-the-art methods on the CSC-Shanmao dataset

    测试条件与方法 定位$\downarrow$(m) 横向$\uparrow$(%) 纵向$\uparrow$(%) 方向$\downarrow$($^\circ$) 方向$\uparrow$(%)
    均值 中值 1 m 3 m 5 m 1 m 3 m 5 m 均值 中值 1$^\circ$ 3$^\circ$ 5$^\circ$
    $\pm 10^\circ$, 结构化数据 LM[60] 8.69 4.96 24.74 57.93 65.95 31.21 62.07 76.55 1.68 1.25 42.16 83.45 95.09
    文献[66]中的方法 16.06 15.61 0.66 4.45 16.12 4.59 14.59 25.43 3.98 3.31 15.40 46.26 69.74
    CCVPE[67] 5.99 1.58 73.02 88.62 90.43 47.16 71.63 78.53 5.99 5.64 6.98 22.93 43.19
    FG2[88] 8.09 7.58 16.49 50.46 76.12 8.62 26.67 42.27 7.80 7.00 5.66 18.28 33.45
    $\pm 10^\circ$, 非结构化数据 LM[60] 4.77 3.86 31.47 56.70 81.23 41.48 66.08 77.10 2.46 1.56 41.64 66.40 83.44
    文献[66]中的方法 20.23 19.20 2.44 8.20 16.51 3.48 11.28 18.50 4.84 4.20 11.75 36.14 58.04
    CCVPE[67] 35.59 37.69 0.03 0.07 0.09 0.02 0.07 0.11 7.96 8.48 0.08 0.21 0.31
    FG2[88] 8.82 7.31 13.88 41.18 63.38 9.35 31.52 50.36 10.32 9.19 4.20 12.35 23.50
    下载: 导出CSV
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  • 收稿日期:  2025-06-03
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