Vision-based active safety system for automatic stopping

Milanés, Vicente; Llorca, David Fernández; Villagrá, Jorge; Pérez, Joshue; Parra, I.; González, Carlos; Sotelo, Miguel Ángel

doi:10.1016/j.eswa.2012.03.047

Cited by 28 publications

(18 citation statements)

References 28 publications

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“…Applications such as an autonomous overtaking system (Milanés, Llorca, Villagrá, Pérez.Fernández, et al, 2012) or automatic stopping (Milanés, Llorca, Villagrá, Pérez, Parra, et al, 2012) are based on advanced visión together with control applications. Other classical applications are advanced localization (Gruyer, Belaroussi, & Revilloud, 2016), pedestrian detection , driver drowsiness detection (Jo, Lee, Park, Kim, & Kim, 2014), lañe departure (Son, Yoo, Kim, & Sohn, 2015), rear obstaele detection (Kim, Choi, Yoo, Yang, & Sohn, 2015), and roundabout moving obstacle detection (Hassannejad, Medici, Cardarelli, & Cerri, 2015).…”

Section: State Of the Artmentioning

confidence: 99%

Motorcycle detection for ADAS through camera and V2V Communication, a comparative analysis of two modern technologies

Anaya¹,

Ponz

Garca

et al. 2017

Expert Systems with Applications

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Section: State Of the Artmentioning

confidence: 99%

Motorcycle detection for ADAS through camera and V2V Communication, a comparative analysis of two modern technologies

Anaya¹,

Ponz

Garca

et al. 2017

Expert Systems with Applications

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“…Ultrasonic sensors are commonly applied to short distance obstacle detection (1 to 3 metres) during parking manoeuvres. Vision sensors are applied for many different tasks such as vehicle detection [19], [20] or autonomous pedestrian collision avoidance [21], [22]. These types of sensors have the advantage that they are cheap and polyvalent, but they are sensitive to weather conditions.…”

Section: Hardware Descriptionmentioning

confidence: 99%

“…In 2005 Park Shuttle II [8], [9] started an automated transport service at Rivium Business Park on the outskirts of Rotterdam. The vehicles exhibited an increased capacity of [20][21][22][23][24] passengers and drove at 32 km/h along a 1.3 km track with five stations. Furthermore, vehicles were capable of stopping automatically when they detected an object in their path.…”

Section: Introductionmentioning

confidence: 99%

Autonomous Navigation and Obstacle Avoidance of a Micro-Bus

Fernández

Domínguez

Llorca

et al. 2013

International Journal of Advanced Robotic Systems

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At present, the topic of automated vehicles is one of the most promising research areas in the field of Intelligent Transportation Systems (ITS). The use of automated vehicles for public transportation also contributes to reductions in congestion levels and to improvements in traffic flow. Moreover, electrical public autonomous vehicles are environmentally friendly, provide better air quality and contribute to energy conservation.The driverless public transportation systems, which are at present operating in some airports and train stations, are restricted to dedicated roads and exhibit serious trouble dynamically avoiding obstacles in the trajectory. In this paper, an electric autonomous mini-bus is presented. All datasets used in this article were collected during the experiments carried out in the demonstration event of the 2012 IEEE Intelligent Vehicles Symposium that took place in Alcalá de Henares (Spain). The demonstration consisted of a route 725 metres long containing a list of latitude-longitude points (waypoints). The mini-bus was capable of driving autonomously from one waypoint to another using a GPS sensor. Furthermore, the vehicle is provided with a multi-beam Laser Imaging Detection and Ranging (LIDAR) sensor for surrounding reconstruction and obstacle detection. When an obstacle is detected in the planned path, the planned route is modified in order to avoid the obstacle and continue its way to the end of the mission. On the demonstration day, a total of 196 attendees had the opportunity to get a ride on the vehicles. A total of 28 laps were successfully completed in full autonomous mode in a private circuit located in the National Institute for Aerospace Research (INTA), Spain. In other words, the system completed 20.3 km of driverless navigation and obstacle avoidance.

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“…If the warning is not considered by the driver and the object are near, and then the ABS will perform braking gradually from soft to hard brake. Some research in the development of ABS, among others, performed by [11,12,13]. In [11] and [12] were examined the use of cameras for ABS, whereas [13] developed ABS for smart vehicles.…”

Section: Introductionmentioning

confidence: 99%

Hardware simulation of automatic braking system based on fuzzy logic control

Basjaruddin

Kuspriyanto

Suhendar

et al. 2016

J. Mechatron. Electr. Power Veh. Technol.

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In certain situations, a moving or stationary object can be a barrier for a vehicle. People and vehicles crossing could potentially get hit by a vehicle. Objects around roads as sidewalks, road separator, power poles, and railroad gates are also a potential source of danger when the driver is inattentive in driving the vehicle. A device that can help the driver to brake automatically is known as Automatic Braking System (ABS). ABS is a part of the Advanced Driver Assistance Systems (ADAS), which is a device designed to assist the driver in driving the process. This device was developed to reduce human error that is a major cause of traffic accidents. This paper presents the design of ABS based on fuzzy logic which is simulated in hardware by using a remote control car. The inputs of fuzzy logic are the speed and distance of the object in front of the vehicle, while the output of fuzzy logic is the intensity of braking. The test results on the three variations of speed: slow-speed, medium-speed, and high-speed shows that the design of ABS can work according to design.

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Vision-based active safety system for automatic stopping

Cited by 28 publications

References 28 publications

Motorcycle detection for ADAS through camera and V2V Communication, a comparative analysis of two modern technologies

Motorcycle detection for ADAS through camera and V2V Communication, a comparative analysis of two modern technologies

Autonomous Navigation and Obstacle Avoidance of a Micro-Bus

Hardware simulation of automatic braking system based on fuzzy logic control

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