Embedded vision system for mobile robot navigation

Sawasaki, Naoyuki; Nakao, Manabu; Yamamoto, Yoshinobu; Okabayashi, K.

doi:10.1109/robot.2006.1642108

Cited by 19 publications

(5 citation statements)

References 9 publications

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“…They collaborate to realize the needed functions. The collocations of processors include SIMD (Single Instruction Multiple Data) processor with micro-controller [19], [22] , DSP with FPGA [12]- [14] , FPGA with ANN (Artificial Neural Network) [18] , and so on. The cost of the EVS based on this architecture is higher than the singular processor architecture, as the design circuit is complicated.…”

Section: A Architecture Of Image Processing Modulementioning

confidence: 99%

“…An EVS was proposed in [12] , which is composed of a DSP and a dedicated LSI (Large-scale integration). Some low-level image processing is implemented by LSI, such as spatial filtering, feature extraction and block matching operations.…”

Section: A Architecture Of Image Processing Modulementioning

confidence: 99%

“…Figure 14 gives the results, green and blue points are feature points that match with the map, yellow points are feature points that do not match with the map, the red point is an estimated current position. The system operates at 86 MHz, and the power consumption is only 10 W. Figure 12: System architecture [12] Figure 13: Map and path data [12] Figure 14: Navigation experiment results [12] An EVS based on DSP and FPGA was described in [13] , where the DSP is used as the main processor and the FPGA is used as the coprocessor. Both the DSP and FPGA are driven in parallel for the execution of crucial parts of the vision algorithms.…”

Section: A Architecture Of Image Processing Modulementioning

confidence: 99%

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Development of the Embedded Vision System: A Survey

Zou

2009

Measurement and Control

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Recently embedded technology has been widely applied to machine vision and embedded vision systems are more and more popular. This paper reviews the advances on embedded vision systems, and then compares and analyzes their frameworks in processing ability, cost and performance. A discussion is provided for some unsolved problems for embedded vision systems. Finally, the future of embedded vision system is outlined.

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Section: A Architecture Of Image Processing Modulementioning

confidence: 99%

Section: A Architecture Of Image Processing Modulementioning

confidence: 99%

Section: A Architecture Of Image Processing Modulementioning

confidence: 99%

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Development of the Embedded Vision System: A Survey

Zou

2009

Measurement and Control

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“…Additionally, in [8], an intelligent embedded vision system to implement different image filters and perform image correlation and transformation at up to 667 frames per second was proposed. In [9], an embedded vision system was proposed specifically for mobile robot navigation and low power consumption. This embedded system accelerates the basic image processing algorithms required in a mobile robot application, such as low-level image processing, spatial filtering, feature extraction, and block matching operations.…”

Section: Introductionmentioning

confidence: 99%

An Embedded Real-Time Red Peach Detection System Based on an OV7670 Camera, ARM Cortex-M4 Processor and 3D Look-Up Tables

Teixidó

Font

Pallejà

et al. 2012

Sensors

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This work proposes the development of an embedded real-time fruit detection system for future automatic fruit harvesting. The proposed embedded system is based on an ARM Cortex-M4 (STM32F407VGT6) processor and an Omnivision OV7670 color camera. The future goal of this embedded vision system will be to control a robotized arm to automatically select and pick some fruit directly from the tree. The complete embedded system has been designed to be placed directly in the gripper tool of the future robotized harvesting arm. The embedded system will be able to perform real-time fruit detection and tracking by using a three-dimensional look-up-table (LUT) defined in the RGB color space and optimized for fruit picking. Additionally, two different methodologies for creating optimized 3D LUTs based on existing linear color models and fruit histograms were implemented in this work and compared for the case of red peaches. The resulting system is able to acquire general and zoomed orchard images and to update the relative tracking information of a red peach in the tree ten times per second.

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“…However, unambiguous evaluation of the environment is computationally costly since most vision systems (pinhole camera) operate by severely collapsing the 3D world into 2D [5]. While it does not pose a serious limitation on mobile robots that can accommodate suitable vision hardware [6] [7][8] [9], it is a challenge for mobile robots with small footprint to equip sophisticated image processing hardware for real time application [10] [11] [12][13] [14]. Some methods to alleviate computational overheads include using biologically inspired compound-eye like vision systems [5][15] [16].…”

Section: Introductionmentioning

confidence: 99%

Edge detection using structured laser pattern and vision for mobile robot navigation

Xie

Wang

Guo

et al. 2011

2011 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM)

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This paper presents a vision-guided navigation strategy based on edge detection. This controlled strategy is computationally simple and suitable for small mobile robots with limited onboard resources, such as a mobile sensor node for structural health monitoring. Traditional vision navigation relies on detecting and extracting features from structured environment or natural scene as references for localization; such approach requires heavy computations for real-time operation and hence results in bulky designs of the mobile robots. To overcome this limitation, a new navigation strategy is proposed by monitoring the change of a projected laser pattern on different obstacles such as edges, walls and corners. Due to the characteristics of laser light, the pattern can be easily captured for fast image processing. Based on the pattern changes, a controlled method for navigation on a plane is designed and the dynamics of a wheeled robot is formulated for simulation. Illustrative applications are provided by results of edge detection using an onboard camera and feedback control for a wheeled robot navigation.

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Embedded vision system for mobile robot navigation

Cited by 19 publications

References 9 publications

Development of the Embedded Vision System: A Survey

Development of the Embedded Vision System: A Survey

An Embedded Real-Time Red Peach Detection System Based on an OV7670 Camera, ARM Cortex-M4 Processor and 3D Look-Up Tables

Edge detection using structured laser pattern and vision for mobile robot navigation

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