A processor-implemented method, system, and/or computer program product guides mobility-impaired pedestrians. Mobile tracking readings are received from multiple mobility assistance devices, each of which has an affixed tracking device. Based on these mobile tracking readings, multiple pedestrian ro
A processor-implemented method, system, and/or computer program product guides mobility-impaired pedestrians. Mobile tracking readings are received from multiple mobility assistance devices, each of which has an affixed tracking device. Based on these mobile tracking readings, multiple pedestrian routes for mobility-impaired pedestrians, including an optimal pedestrian route that has the highest tracking history to a desired destination, are generated.
대표청구항▼
1. A processor-implemented method of guiding mobility-impaired pedestrians, the processor-implemented method comprising: a processor receiving a plurality of mobile tracking readings from each of multiple mobility assistance devices, wherein a tracking device is affixed to each of the multiple mobil
1. A processor-implemented method of guiding mobility-impaired pedestrians, the processor-implemented method comprising: a processor receiving a plurality of mobile tracking readings from each of multiple mobility assistance devices, wherein a tracking device is affixed to each of the multiple mobility assistance devices to generate the plurality of mobile tracking readings;the processor identifying a plurality of pedestrian routes taken by the multiple mobility assistance devices to a desired destination, wherein the plurality of pedestrian routes are identified by the plurality of mobile tracking readings generated by tracking devices affixed to the multiple mobility assistance devices;the processor identifying at least one optimal pedestrian route from the plurality of pedestrian routes, wherein said at least one optimal pedestrian route is identified as having more mobile tracking readings than any other pedestrian route from the plurality of pedestrian routes; andthe processor transmitting directions that describe said at least one optimal pedestrian route, to the desired destination, to a current mobility-impaired pedestrian for traveling to a destination location. 2. The processor-implemented method of claim 1, further comprising: the processor detecting a change in altitude location of at least one of the multiple mobility assistance devices after losing and then subsequently regaining a signal from the tracking device on said at least one of the multiple mobility assistance devices;the processor interpreting said change in altitude location after losing and then subsequently regaining said signal from the tracking device as being caused by said at least one of the multiple mobility assistance devices being transported in an elevator; andthe processor transmitting a location of said elevator to said current mobility-impaired pedestrian. 3. A computer program product for guiding mobility-impaired pedestrians, the computer program product comprising: a non-transitory computer readable storage media;first program instructions to receive a plurality of mobile tracking readings from each of multiple mobility assistance devices, wherein a tracking device is affixed to each of the multiple mobility assistance devices to generate the plurality of mobile tracking readings;second program instructions to identify a plurality of pedestrian routes taken by the multiple mobility assistance devices to a desired destination, wherein the plurality of pedestrian routes are identified by the plurality of mobile tracking readings generated by tracking devices affixed to the multiple mobility assistance devices;third program instructions to identify at least one optimal pedestrian route from the plurality of pedestrian routes, wherein said at least one optimal pedestrian route is identified as having more mobile tracking readings than any other pedestrian route from the plurality of pedestrian routes; andfourth program instructions to transmit directions that describe said at least one optimal pedestrian route, to the desired destination, to a current mobility-impaired pedestrian for traveling to a destination location; and wherein the first, second, third, and fourth program instructions are stored on the non-transitory computer readable storage media. 4. The computer program product of claim 3, further comprising: fifth program instructions to detect a change in altitude location of at least one of the multiple mobility assistance devices after losing and then subsequently regaining a signal from the tracking device on said at least one of the multiple mobility assistance devices;sixth program instructions to interpret said change in altitude location after losing and then subsequently regaining said signal from the tracking device as being caused by said at least one of the multiple mobility assistance devices being transported in an elevator; andseventh program instructions to transmit a location of said elevator to said current mobility-impaired pedestrian; and wherein the fifth, sixth, and seventh program instructions are stored on the non-transitory computer readable storage media. 5. A computer system comprising: a processor, a computer readable memory, and a non-transitory computer readable storage media;first program instructions to receive a plurality of mobile tracking readings from each of multiple mobility assistance devices, wherein a tracking device is affixed to each of the multiple mobility assistance devices to generate the plurality of mobile tracking readings;second program instructions to identify a plurality of pedestrian routes taken by the multiple mobility assistance devices to a desired destination, wherein the plurality of pedestrian routes are identified by the plurality of mobile tracking readings generated by tracking devices affixed to the multiple mobility assistance devices;third program instructions to identify at least one optimal pedestrian route from the plurality of pedestrian routes, wherein said at least one optimal pedestrian route is identified as having more mobile tracking readings than any other pedestrian route from the plurality of pedestrian routes; andfourth program instructions to transmit directions that describe said at least one optimal pedestrian route, to the desired destination, to a current mobility-impaired pedestrian for traveling to a destination location; and wherein the first, second, third, and fourth program instructions are stored on the non-transitory computer readable storage media for execution by the processor via the computer readable memory. 6. The computer system of claim 5, further comprising: fifth program instructions to detect a change in altitude location of at least one of the multiple mobility assistance devices after losing and then subsequently regaining a signal from the tracking device on said at least one of the multiple mobility assistance devices;sixth program instructions to interpret said change in altitude location after losing and then subsequently regaining said signal from the tracking device as being caused by said at least one of the multiple mobility assistance devices being transported in an elevator; andseventh program instructions to transmit a location of said elevator to said current mobility-impaired pedestrian; and wherein the fifth, sixth, and seventh program instructions are stored on the non-transitory computer readable storage media for execution by the processor via the computer readable memory.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (25)
Merk John (Winchester MA) Day David R. (Boxford MA) Newton Robert E. (Tewksbury MA), Acoustic sensing.
Egorov Alexandr F. (Shmidtovsky Proezd ; 15 ; kv. 25 Moscow SUX) Ryzhnev Vadim J. (Ryazansky prospekt ; 95 ; Korpus 4 ; kv. 20 Moscow SUX) Simonovsky Dmitry K. (ulitsa Vvedenskogo ; 17 ; korpus 1 ; k, Method of determining the quantitative content of gaseous or vaporous impurity in a gas mixture and a device for accompl.
Byalko ; Mikhail V. ; Kirko ; Elena V. ; Perlovsky ; Rafael S. ; Ryzhne v ; Vadim J., Pneumatic detector of gas and vapor contaminants in atmosphere of industrial buildings.
Yamashita, Shunzo; Suzuki, Kei; Aritsuka, Toshiyuki; Nakano, Sadaki, Quality monitoring system for building structure, quality monitoring method for building structure and semiconductor integrated circuit device.
McGovern Paul A. (440 Second St. Dunellen NJ 08812) Zambuto Mauro (445 W. 23 St. New York NY 10011), Surveying technique with correction of optical errors caused by atmospheric turbulence.
Friedlander, Robert R.; Kraemer, James R., System and method for detection of earthquakes and tsunamis, and hierarchical analysis, threat classification, and interface to warning systems.
Carrieri, Arthur H.; Roese, Erik S.; Colclough, Stephen J.; Schlitzkus, Peter J.; Younger, V. Kenneth; Orndoff, James R., Thermal luminescence liquid monitoring system and method.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.