Telemetry device for capturing vehicle environment and operational status history
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B60K-035/00
G07C-005/00
G01C-021/34
B60W-040/09
출원번호
US-0711084
(2015-05-13)
등록번호
US-9792736
(2017-10-17)
발명자
/ 주소
Koebler, Martin
Goldstein, Nicole G.
Brown, Stephen J.
Harper, Jason H.
출원인 / 주소
Invently Automotive Inc.
대리인 / 주소
Maiorana, PC, Christopher P.
인용정보
피인용 횟수 :
1인용 특허 :
46
초록▼
Described herein are devices, systems, and methods for managing the power consumption of an automotive vehicle, and thereby for optimizing the power consumption of the vehicle. The devices and systems for managing the power consumption of the vehicle typically include power management logic that can
Described herein are devices, systems, and methods for managing the power consumption of an automotive vehicle, and thereby for optimizing the power consumption of the vehicle. The devices and systems for managing the power consumption of the vehicle typically include power management logic that can calculate an applied power for the vehicle engine based on information provided from the external environment of the vehicle, the operational status of the vehicle, one or more command inputs from a driver, and one or more operational parameters of the vehicle.
대표청구항▼
1. A vehicle telemetry device comprising: a processor configured to execute control logic;a memory coupled to said processor;a communications element configured to communicate with a wireless communication network; anda sensor interface configured to connect to a plurality of sensors within a vehicl
1. A vehicle telemetry device comprising: a processor configured to execute control logic;a memory coupled to said processor;a communications element configured to communicate with a wireless communication network; anda sensor interface configured to connect to a plurality of sensors within a vehicle, wherein (i) said control logic is configured to (a) acquire information from said sensor interface, (b) store said information in said memory, (c) communicate said information to a database external to said vehicle using said wireless communication network and (d) determine a route from a current location of said vehicle to a destination based on said information, (ii) said information from said sensor interface comprises a combination of (a) driver information, (b) vehicle operational status information and (c) external information received from said plurality of sensors, (iii) said information is stored in said database as records associated with a driver identity, a date, a time and location information of said vehicle corresponding to when said information was acquired and (iv) said driver information includes (a) said destination explicitly provided by a driver, (b) a preferred speed, (c) a maximum and minimum range of speed adjustments and (d) a preferred route to said destination. 2. The device according to claim 1, wherein said external information is related to an external environment of said current location of said vehicle. 3. The device according to claim 1, wherein said external information comprises one or more of a current elevation of said vehicle, upcoming elevations of said vehicle, a current slope/grade of said route, a predicted slope/grade of upcoming route segments, a condition of a known route, a condition of a predicted route, a condition of a portion of said route, traffic surrounding said vehicle, a location of stoplights, a timing of stoplights, a map of a roadway, a present angle of sunlight, a predicted angle of sunlight in said upcoming route segments, weather around said vehicle, a present wind direction, a predicted wind direction in said upcoming route segments, a present wind velocity, a predicted wind velocity in said upcoming route segments, a current temperature, a predicted temperature in said upcoming route segments, a current air pressure, a predicted air pressure in said upcoming route segments, a time of day, a date, a day of week, a visibility, present road conditions, predicted road conditions in said upcoming route segments, and a distance from other vehicles. 4. The device according to claim 1, wherein said external information is acquired by measuring. 5. The device according to claim 1, wherein said external information is detected from inputs. 6. The device according to claim 1, wherein said external information is telemetry data received from a remote data source. 7. The device according to claim 1, wherein said external information is derived from at least one of (i) other information and (ii) combinations of information and analysis logic. 8. The device according to claim 1, wherein said vehicle operational status information is selected from a group consisting of: a current speed of said vehicle, a motor speed, a current orientation of said vehicle, an RPM of said motor of said vehicle, wheel rotations per minute, a battery state, a voltage of a battery, amp hours from said battery, a temperature of said battery, an age of said battery, a number of times said battery has charged and discharged, a tire pressure, a drag force due to rolling resistance of said vehicle, a weight of said vehicle, an amount of air going to an engine, an amount of gas going to said engine, and a weight of a driver. 9. The device according to claim 1, wherein said driver information is comprised of command inputs by said driver to said vehicle, said command inputs comprising at least one of acceleration applied by said driver, and braking applied by said driver. 10. The device according to claim 9, wherein said command inputs comprise inputs by said driver through a user interface element. 11. The device according to claim 9, wherein said command inputs comprise driver behavior measurements acquired by said plurality of sensors. 12. The device according to claim 1, wherein (i) said location information comprises a route segment from a series of route segments and (ii) a record in said database is associated with said route segment. 13. The device according to claim 1, wherein said vehicle operational status information includes (a) a tire pressure, (b) a drag force due to a rolling resistance of said vehicle, (c) a weight of said vehicle, (d) an amount of air going to an engine of said vehicle, (e) an amount of gas going to said engine and (f) a weight of said driver. 14. The device according to claim 1, wherein (i) said external information includes a proximity to other vehicles in a direction of travel of said vehicle and (ii) a speed of said vehicle in said direction of travel is automatically adjusted based on said proximity to avoid a collision. 15. A vehicle telemetry device comprising: a processor configured to execute control logic;a memory coupled to said processor;a communications element configured to communicate with a wireless communication network; anda sensor interface configured to connect to a plurality of sensors within a vehicle, wherein (i) said control logic is configured to (a) acquire information from said sensor interface, (b) store said information in said memory, (c) communicate said information to a database external to said vehicle using said wireless communication network and (d) determine a route from a current location of said vehicle to a destination based on said information, (ii) said information is received from said plurality of sensors, (iii) said information is stored in said database as records associated with a driver identity, a date, a time and location information of said vehicle corresponding to when said information was acquired, (iv) said device is connected to a user interface unit configured to present messages to a driver based on processing of said information and (v) said information includes (a) a tire pressure, (b) a drag force due to a rolling resistance of said vehicle and (c) a weight of said vehicle. 16. The device according to claim 15, wherein said information further includes (a) said destination explicitly provided by said driver, (b) a preferred speed, (c) a maximum and minimum range of speed adjustments, (d) a preferred route to said destination, (e) an amount of air going to an engine of said vehicle, (f) an amount of gas going to said engine and (g) a weight of said driver. 17. The device according to claim 15, wherein said control logic is remotely updatable from a remote source. 18. A vehicle telemetry device comprising: a processor configured to execute control logic;a memory coupled to said processor;a communications element configured to communicate with a wireless communication network; anda sensor interface configured to connect to a plurality of sensors within a vehicle, wherein (i) said control logic is configured to (a) acquire information from said sensor interface, (b) store said information in said memory, (c) communicate said information to a database external to said vehicle using said wireless communication network and (d) determine a route from a current location of said vehicle to a destination based on said information, (ii) said information from said sensor interface comprises a combination of (a) driver identity information, (b) information from an environment external to said vehicle and (c) vehicle operational status information from said plurality of sensors, (iii) said information is stored in said database as records associated with said driver identity information, a date, a time and location information of said vehicle corresponding to when said information was acquired, (iv) said device is connected to a user interface unit that presents messages to a driver based on processing of said information, (v) said vehicle operational status information includes (a) an amount of air going to an engine of said vehicle, (b) an amount of gas going to said engine and (c) a weight of said driver. 19. The device according to claim 18, wherein said information further includes (a) said destination explicitly provided by said driver, (b) a preferred speed, (c) a maximum and minimum range of speed adjustments, (d) a preferred route to said destination, (e) a tire pressure, (f) a drag force due to a rolling resistance of said vehicle and (g) a weight of said vehicle. 20. The device according to claim 18, wherein said route minimizes an amount of gas consumed by said vehicle to reach said destination.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (46)
Tamai Goro ; Hoang Tony T. ; Richey Dennis T. ; Downs Robert C., Apparatus and method for a torque and fuel control system for a hybrid vehicle.
Kubalak Thomas P. (1112 - 45th Ave. NE. Minneapolis MN 55421) Berghoff Gene M. (6923 Woodland Dr. Eden Prairie MN 55344) Palmer William J. (4800 W. 111th Bloomington MN 55437), Electronic fuel management system.
Bauer, Wolf-Dietrich; Mayer, Christian Michael; Schwarzhaupt, Andreas; Spiegelberg, Gernot, Electronically actuated drive train in a motor vehicle and an associated operating method.
Naden,Gary; Schamber,Stephen; Tanner,Ronnie; Quillin,Scott, Location monitoring and transmitting device, method, and computer program product using a simplex satellite transmitter.
Allen,Robert; Bain,William O., System having a power adapter that generates a data signal based on the state of a external power source that is used to manage the power consumption of a CPU.
McClellan Scott B. ; Henderson Robert M. ; Russon Verlin G. ; Pungor Andras ; Lyons Mike J., Vehicle motion detection and recording method and apparatus.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.