IKap: Kinematics-Aware Planning with Imperative Learning

Qihang Li; Zhuoqun Chen; Haoze Zheng; Haonan He; Zitong Zhan; Shaoshu Su; Junyi Geng; Chen Wang

doi:10.1109/ICRA55743.2025.11127660

IKap: Kinematics-Aware Planning with Imperative Learning

Qihang Li
, Zhuoqun Chen
, Haoze Zheng
, Haonan He
, Zitong Zhan
, Shaoshu Su
, Junyi Geng
, Chen Wang

Department of Computer Science and Engineering

SUNY Buffalo
Carnegie Mellon University
Pennsylvania State University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

2 Scopus citations

Abstract

Trajectory planning in robotics aims to generate collision-free pose sequences that can be reliably executed. Recently, vision-to-planning systems have gained increasing attention for their efficiency and ability to interpret and adapt to surrounding environments. However, traditional modular systems suffer from increased latency and error propagation, while purely data-driven approaches often overlook the robot's kinematic constraints. This oversight leads to discrepancies between planned trajectories and those that are executable. To address these challenges, we propose iKap, a novel vision-toplanning system that integrates the robot's kinematic model directly into the learning pipeline. iKap employs a self-supervised learning approach and incorporates the state transition model within a differentiable bi-level optimization framework. This integration ensures the network learns collision-free waypoints while satisfying kinematic constraints, enabling gradient backpropagation for end-to-end training. Our experimental results demonstrate that iKap achieves higher success rates and reduced latency compared to the state-of-the-art methods. Besides the complete system, iKap offers a visual-to-planning network that seamlessly works with various controllers, providing a robust solution for robots navigating complex environments.

Original language	English
Title of host publication	2025 IEEE International Conference on Robotics and Automation, ICRA 2025
Editors	Christian Ott, Henny Admoni, Sven Behnke, Stjepan Bogdan, Aude Bolopion, Youngjin Choi, Fanny Ficuciello, Nicholas Gans, Clement Gosselin, Kensuke Harada, Erdal Kayacan, H. Jin Kim, Stefan Leutenegger, Zhe Liu, Perla Maiolino, Lino Marques, Takamitsu Matsubara, Anastasia Mavromatti, Mark Minor, Jason O'Kane, Hae Won Park, Hae-Won Park, Ioannis Rekleitis, Federico Renda, Elisa Ricci, Laurel D. Riek, Lorenzo Sabattini, Shaojie Shen, Yu Sun, Pierre-Brice Wieber, Katsu Yamane, Jingjin Yu
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	10164-10170
Number of pages	7
ISBN (Electronic)	9798331541392
DOIs	https://doi.org/10.1109/ICRA55743.2025.11127660
State	Published - 2025
Event	2025 IEEE International Conference on Robotics and Automation, ICRA 2025 - Atlanta, United States Duration: May 19 2025 → May 23 2025

Publication series

Name	Proceedings - IEEE International Conference on Robotics and Automation
ISSN (Print)	1050-4729

Conference

Conference	2025 IEEE International Conference on Robotics and Automation, ICRA 2025
Country/Territory	United States
City	Atlanta
Period	05/19/25 → 05/23/25

Access to Document

10.1109/ICRA55743.2025.11127660

Cite this

Li, Q., Chen, Z., Zheng, H., He, H., Zhan, Z., Su, S., Geng, J., & Wang, C. (2025). IKap: Kinematics-Aware Planning with Imperative Learning. In C. Ott, H. Admoni, S. Behnke, S. Bogdan, A. Bolopion, Y. Choi, F. Ficuciello, N. Gans, C. Gosselin, K. Harada, E. Kayacan, H. J. Kim, S. Leutenegger, Z. Liu, P. Maiolino, L. Marques, T. Matsubara, A. Mavromatti, M. Minor, J. O'Kane, H. W. Park, H.-W. Park, I. Rekleitis, F. Renda, E. Ricci, L. D. Riek, L. Sabattini, S. Shen, Y. Sun, P.-B. Wieber, K. Yamane, ... J. Yu (Eds.), 2025 IEEE International Conference on Robotics and Automation, ICRA 2025 (pp. 10164-10170). (Proceedings - IEEE International Conference on Robotics and Automation). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/ICRA55743.2025.11127660

Li, Qihang ; Chen, Zhuoqun ; Zheng, Haoze et al. / IKap : Kinematics-Aware Planning with Imperative Learning. 2025 IEEE International Conference on Robotics and Automation, ICRA 2025. editor / Christian Ott ; Henny Admoni ; Sven Behnke ; Stjepan Bogdan ; Aude Bolopion ; Youngjin Choi ; Fanny Ficuciello ; Nicholas Gans ; Clement Gosselin ; Kensuke Harada ; Erdal Kayacan ; H. Jin Kim ; Stefan Leutenegger ; Zhe Liu ; Perla Maiolino ; Lino Marques ; Takamitsu Matsubara ; Anastasia Mavromatti ; Mark Minor ; Jason O'Kane ; Hae Won Park ; Hae-Won Park ; Ioannis Rekleitis ; Federico Renda ; Elisa Ricci ; Laurel D. Riek ; Lorenzo Sabattini ; Shaojie Shen ; Yu Sun ; Pierre-Brice Wieber ; Katsu Yamane ; Jingjin Yu. Institute of Electrical and Electronics Engineers Inc., 2025. pp. 10164-10170 (Proceedings - IEEE International Conference on Robotics and Automation).

@inproceedings{56a995fc30a44f6db15814865d26f4e8,

title = "IKap: Kinematics-Aware Planning with Imperative Learning",

abstract = "Trajectory planning in robotics aims to generate collision-free pose sequences that can be reliably executed. Recently, vision-to-planning systems have gained increasing attention for their efficiency and ability to interpret and adapt to surrounding environments. However, traditional modular systems suffer from increased latency and error propagation, while purely data-driven approaches often overlook the robot's kinematic constraints. This oversight leads to discrepancies between planned trajectories and those that are executable. To address these challenges, we propose iKap, a novel vision-toplanning system that integrates the robot's kinematic model directly into the learning pipeline. iKap employs a self-supervised learning approach and incorporates the state transition model within a differentiable bi-level optimization framework. This integration ensures the network learns collision-free waypoints while satisfying kinematic constraints, enabling gradient backpropagation for end-to-end training. Our experimental results demonstrate that iKap achieves higher success rates and reduced latency compared to the state-of-the-art methods. Besides the complete system, iKap offers a visual-to-planning network that seamlessly works with various controllers, providing a robust solution for robots navigating complex environments.",

author = "Qihang Li and Zhuoqun Chen and Haoze Zheng and Haonan He and Zitong Zhan and Shaoshu Su and Junyi Geng and Chen Wang",

note = "Publisher Copyright: {\textcopyright} 2025 IEEE.; 2025 IEEE International Conference on Robotics and Automation, ICRA 2025 ; Conference date: 19-05-2025 Through 23-05-2025",

year = "2025",

doi = "10.1109/ICRA55743.2025.11127660",

language = "English",

series = "Proceedings - IEEE International Conference on Robotics and Automation",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

pages = "10164--10170",

editor = "Christian Ott and Henny Admoni and Sven Behnke and Stjepan Bogdan and Aude Bolopion and Youngjin Choi and Fanny Ficuciello and Nicholas Gans and Clement Gosselin and Kensuke Harada and Erdal Kayacan and Kim, \{H. Jin\} and Stefan Leutenegger and Zhe Liu and Perla Maiolino and Lino Marques and Takamitsu Matsubara and Anastasia Mavromatti and Mark Minor and Jason O'Kane and Park, \{Hae Won\} and Hae-Won Park and Ioannis Rekleitis and Federico Renda and Elisa Ricci and Riek, \{Laurel D.\} and Lorenzo Sabattini and Shaojie Shen and Yu Sun and Pierre-Brice Wieber and Katsu Yamane and Jingjin Yu",

booktitle = "2025 IEEE International Conference on Robotics and Automation, ICRA 2025",

address = "United States",

}

Li, Q, Chen, Z, Zheng, H, He, H, Zhan, Z, Su, S, Geng, J & Wang, C 2025, IKap: Kinematics-Aware Planning with Imperative Learning. in C Ott, H Admoni, S Behnke, S Bogdan, A Bolopion, Y Choi, F Ficuciello, N Gans, C Gosselin, K Harada, E Kayacan, HJ Kim, S Leutenegger, Z Liu, P Maiolino, L Marques, T Matsubara, A Mavromatti, M Minor, J O'Kane, HW Park, H-W Park, I Rekleitis, F Renda, E Ricci, LD Riek, L Sabattini, S Shen, Y Sun, P-B Wieber, K Yamane & J Yu (eds), 2025 IEEE International Conference on Robotics and Automation, ICRA 2025. Proceedings - IEEE International Conference on Robotics and Automation, Institute of Electrical and Electronics Engineers Inc., pp. 10164-10170, 2025 IEEE International Conference on Robotics and Automation, ICRA 2025, Atlanta, United States, 05/19/25. https://doi.org/10.1109/ICRA55743.2025.11127660

IKap: Kinematics-Aware Planning with Imperative Learning. / Li, Qihang; Chen, Zhuoqun; Zheng, Haoze et al.
2025 IEEE International Conference on Robotics and Automation, ICRA 2025. ed. / Christian Ott; Henny Admoni; Sven Behnke; Stjepan Bogdan; Aude Bolopion; Youngjin Choi; Fanny Ficuciello; Nicholas Gans; Clement Gosselin; Kensuke Harada; Erdal Kayacan; H. Jin Kim; Stefan Leutenegger; Zhe Liu; Perla Maiolino; Lino Marques; Takamitsu Matsubara; Anastasia Mavromatti; Mark Minor; Jason O'Kane; Hae Won Park; Hae-Won Park; Ioannis Rekleitis; Federico Renda; Elisa Ricci; Laurel D. Riek; Lorenzo Sabattini; Shaojie Shen; Yu Sun; Pierre-Brice Wieber; Katsu Yamane; Jingjin Yu. Institute of Electrical and Electronics Engineers Inc., 2025. p. 10164-10170 (Proceedings - IEEE International Conference on Robotics and Automation).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - IKap

T2 - 2025 IEEE International Conference on Robotics and Automation, ICRA 2025

AU - Li, Qihang

AU - Chen, Zhuoqun

AU - Zheng, Haoze

AU - He, Haonan

AU - Zhan, Zitong

AU - Su, Shaoshu

AU - Geng, Junyi

AU - Wang, Chen

PY - 2025

Y1 - 2025

N2 - Trajectory planning in robotics aims to generate collision-free pose sequences that can be reliably executed. Recently, vision-to-planning systems have gained increasing attention for their efficiency and ability to interpret and adapt to surrounding environments. However, traditional modular systems suffer from increased latency and error propagation, while purely data-driven approaches often overlook the robot's kinematic constraints. This oversight leads to discrepancies between planned trajectories and those that are executable. To address these challenges, we propose iKap, a novel vision-toplanning system that integrates the robot's kinematic model directly into the learning pipeline. iKap employs a self-supervised learning approach and incorporates the state transition model within a differentiable bi-level optimization framework. This integration ensures the network learns collision-free waypoints while satisfying kinematic constraints, enabling gradient backpropagation for end-to-end training. Our experimental results demonstrate that iKap achieves higher success rates and reduced latency compared to the state-of-the-art methods. Besides the complete system, iKap offers a visual-to-planning network that seamlessly works with various controllers, providing a robust solution for robots navigating complex environments.

AB - Trajectory planning in robotics aims to generate collision-free pose sequences that can be reliably executed. Recently, vision-to-planning systems have gained increasing attention for their efficiency and ability to interpret and adapt to surrounding environments. However, traditional modular systems suffer from increased latency and error propagation, while purely data-driven approaches often overlook the robot's kinematic constraints. This oversight leads to discrepancies between planned trajectories and those that are executable. To address these challenges, we propose iKap, a novel vision-toplanning system that integrates the robot's kinematic model directly into the learning pipeline. iKap employs a self-supervised learning approach and incorporates the state transition model within a differentiable bi-level optimization framework. This integration ensures the network learns collision-free waypoints while satisfying kinematic constraints, enabling gradient backpropagation for end-to-end training. Our experimental results demonstrate that iKap achieves higher success rates and reduced latency compared to the state-of-the-art methods. Besides the complete system, iKap offers a visual-to-planning network that seamlessly works with various controllers, providing a robust solution for robots navigating complex environments.

UR - https://www.scopus.com/pages/publications/105016531679

U2 - 10.1109/ICRA55743.2025.11127660

DO - 10.1109/ICRA55743.2025.11127660

M3 - Conference contribution

AN - SCOPUS:105016531679

T3 - Proceedings - IEEE International Conference on Robotics and Automation

SP - 10164

EP - 10170

BT - 2025 IEEE International Conference on Robotics and Automation, ICRA 2025

A2 - Ott, Christian

A2 - Admoni, Henny

A2 - Behnke, Sven

A2 - Bogdan, Stjepan

A2 - Bolopion, Aude

A2 - Choi, Youngjin

A2 - Ficuciello, Fanny

A2 - Gans, Nicholas

A2 - Gosselin, Clement

A2 - Harada, Kensuke

A2 - Kayacan, Erdal

A2 - Kim, H. Jin

A2 - Leutenegger, Stefan

A2 - Liu, Zhe

A2 - Maiolino, Perla

A2 - Marques, Lino

A2 - Matsubara, Takamitsu

A2 - Mavromatti, Anastasia

A2 - Minor, Mark

A2 - O'Kane, Jason

A2 - Park, Hae Won

A2 - Park, Hae-Won

A2 - Rekleitis, Ioannis

A2 - Renda, Federico

A2 - Ricci, Elisa

A2 - Riek, Laurel D.

A2 - Sabattini, Lorenzo

A2 - Shen, Shaojie

A2 - Sun, Yu

A2 - Wieber, Pierre-Brice

A2 - Yamane, Katsu

A2 - Yu, Jingjin

PB - Institute of Electrical and Electronics Engineers Inc.

Y2 - 19 May 2025 through 23 May 2025

ER -

Li Q, Chen Z, Zheng H, He H, Zhan Z, Su S et al. IKap: Kinematics-Aware Planning with Imperative Learning. In Ott C, Admoni H, Behnke S, Bogdan S, Bolopion A, Choi Y, Ficuciello F, Gans N, Gosselin C, Harada K, Kayacan E, Kim HJ, Leutenegger S, Liu Z, Maiolino P, Marques L, Matsubara T, Mavromatti A, Minor M, O'Kane J, Park HW, Park HW, Rekleitis I, Renda F, Ricci E, Riek LD, Sabattini L, Shen S, Sun Y, Wieber PB, Yamane K, Yu J, editors, 2025 IEEE International Conference on Robotics and Automation, ICRA 2025. Institute of Electrical and Electronics Engineers Inc. 2025. p. 10164-10170. (Proceedings - IEEE International Conference on Robotics and Automation). doi: 10.1109/ICRA55743.2025.11127660

IKap: Kinematics-Aware Planning with Imperative Learning

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