Method and device for sensing of obstacles for an autonomous device
First Claim
1. A method for sensing proximity for an autonomous device, said autonomous device including wheels, a motor, and a microprocessor and proximity sensing system for orientation and guidance of said autonomous device, said proximity sensing system including a transmitter and receivers, said receivers having signal interfaces for transmitting digital signals to said microprocessor and being arranged in one of a slanted plane and along a curved baseline, comprising the steps of:
- transmitting a wave from said transmitter, said wave having a slow propagation and being transmitted within a continuous sector of a normal travelling direction of said autonomous device;
detecting reflections of said wave by a number of said receivers during a predetermined time slot, corresponding to a proximate area, thereby obtaining a three-dimensional direction to an obstacle;
a transmitting digital signals from said number of said receivers to said microprocessor in response to said detecting;
processing said digital signals by said microprocessor and creating an orientation data base within said proximate area;
utilizing said data base continuously for orientation and guidance of said autonomous device with respect to detected obstacles during continued automatic motion of said autonomous device, and obtaining further proximity data for use by said microprocessor in combination with said data base for orientation and guidance of said autonomous device during said continued automatic motion by processing further digital signals transmitted from a number of said receivers to said microprocessor in response to further of said transmitting and detecting on the same wave frequency within said predetermined time slot during said continued automatic motion.
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Abstract
The present invention provides a method and a system for proximate field orientation of an autonomous device and utilizes a transmitted wave having a first frequency of slow propagation, whereby reflections from obstacles within a proximate area are detected. According to the present invention receivers are arranged in a slanted plane or preferably along a curved base-line to, in a simple way, obtain a three-dimensional direction to an obstacle reflecting the frequency of slow propagation. Additionally, an absorber or a screen or a combination thereof is arranged above at least one receiver to act as an "eyebrow" attenuating undesired reflections which at the receiver come from overhead. Additionally, at least one of the receivers along the generally curved base-line is arranged differently in height in relation to the remaining receivers, and preferably the most outer receiver on each side in the line of receivers along the generally curved base-line is arranged differently in height in relation to the remaining receivers for an improvement of the three-dimensional resolution.
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Citations
20 Claims
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1. A method for sensing proximity for an autonomous device, said autonomous device including wheels, a motor, and a microprocessor and proximity sensing system for orientation and guidance of said autonomous device, said proximity sensing system including a transmitter and receivers, said receivers having signal interfaces for transmitting digital signals to said microprocessor and being arranged in one of a slanted plane and along a curved baseline, comprising the steps of:
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transmitting a wave from said transmitter, said wave having a slow propagation and being transmitted within a continuous sector of a normal travelling direction of said autonomous device; detecting reflections of said wave by a number of said receivers during a predetermined time slot, corresponding to a proximate area, thereby obtaining a three-dimensional direction to an obstacle; a transmitting digital signals from said number of said receivers to said microprocessor in response to said detecting; processing said digital signals by said microprocessor and creating an orientation data base within said proximate area; utilizing said data base continuously for orientation and guidance of said autonomous device with respect to detected obstacles during continued automatic motion of said autonomous device, and obtaining further proximity data for use by said microprocessor in combination with said data base for orientation and guidance of said autonomous device during said continued automatic motion by processing further digital signals transmitted from a number of said receivers to said microprocessor in response to further of said transmitting and detecting on the same wave frequency within said predetermined time slot during said continued automatic motion. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 19)
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10. A system for sensing proximity for an autonomous device, said autonomous device including wheels, a motor, and a microprocessor and proximity sensing system for orientation and guidance of said autonomous device, said proximity sensing system including at least a transmitter and a plurality of receivers, said receivers having signal interfaces for transmitting digital signals to said microprocessor and being arranged in one of a slanted plane and along a curved baseline for obtaining direction resolution to obstacles having reflected a wave of slow propagation, said transmitter being structured and arranged to transmit said wave, said wave having a slow propagation and being transmittable within a continuous sector of a normal travelling direction of said autonomous device;
- said receivers being structured and arranged to detect reflections of said wave during a predetermined time slot, corresponding to a proximate area, thereby obtaining a three-dimensional direction to an obstacle;
said receivers further being structured and arranged to transmit digital signals from said receivers to said microprocessor in response to said reflections;
said microprocessor being structured and arranged to process said digital signals and create an orientation data base within said proximate area which is utilized continuously for orientation and guidance of said autonomous device with respect to detected obstacles during continued automatic motion of said autonomous device, and which is used in combination with further proximity data for orientation and guidance of said autonomous device during said continued automatic motion by processing further digital signals transmitted from a number of said receivers to said microprocessor in response to further transmission and detection on the same wave frequency within said predetermined time slot during said continued automatic motion. - View Dependent Claims (11, 12, 13, 14, 15, 16, 17, 18, 20)
- said receivers being structured and arranged to detect reflections of said wave during a predetermined time slot, corresponding to a proximate area, thereby obtaining a three-dimensional direction to an obstacle;
Specification