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`First Inventor
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`Title I (cid:9)
`
`PTO/SB/05 (03-01)
`Approved for use through 10/3112002. OMB 0651-0032
`U.S. Patent and Trademark Office: U.S. DEPARTMENT OF COMMERCE
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`Attorney Docket No. I (cid:9)
`1-23649
`UTILITY
`PATENT APPLICATION
`TRANSMITTAL
`(Only for new nonprovisional applications under 37 CFR 1.53(b)) I Express Mail Label No. (cid:9) I (cid:9)
`
`James E. Smith and Anthony 11. McDonald
`
`I
`til
`Automatic Directional Control System For Vehicle Headlights -
`
`APPLICATION ELEMENTS
`See MPEP chapter 600 concerning utility patent application contents.
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`Assistant Commissioner for Patents
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`Specification (cid:9)
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`- Descriptive title of the invention
`- Cross Reference to Related Applications
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`or a computer program listing appendix
`- Background of the Invention
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`DELETION OF INVENTOR(S)
`(cid:9) Signed statement attached deleting inventor(s)
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`For CONTINUATION OR DIVISIONAL APPS only: The entire disclosure of the prior application, from which an oath or declaration is supplied
`under Box 5b, is considered a part of the disclosure of the accompanying continuation or divisional application and is hereby incorporated by
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`SL Corp. Exhibit 1010
`
`(cid:9)
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`,CERTIFICATE OF MAILING BY "EXPRESS MAIL" (37 CFR 1.10)
`Applicant(s): (cid:9)
`James E. Smith and Anthony B. McDonald
`
`Docket No.
`
`1-23649
`
`Serial No.
`
`Filing Date
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`Examiner
`
`Group Art Unit
`
`Invention: (cid:9) AUTOMATIC DIRECTIONAL CONTROL SYSTEM FOR VEHICLE HEADLIGHTS
`
`I hereby certify that the following correspondence:
`
`UTILITY PATENT APPLICATION
`
`"Express Mail Post Office to Addressee" service under
`is being deposited with the United States Postal Service
`
`Commissioner for Patents, Washington, D.C. 20231 on
`37 CFR 1.10 in an envelope addressed to: The Assistant
`
`
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`(Identify type of correspondence)
`
`October 31, 2002
`(Date)
`
`Betty J. Borger
`(Typed or Printed Name of Person Mailing Correspondence)
`
`(Si 4ri, ature o" Person Mailing Cor tisondence
`
`EL 777901929 US
`("Express Mail" Mailing Label Number)
`
`Note: Each paper must have its own certificate of mailing.
`
`PO6A/REVO2
`
`
`
`TITLE
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`AUTOMATIC DIRECTIONAL CONTROL
`SYSTEM FOR VEHICLE HEADLIGHTS
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`CROSS REFERENCE TO RELATED APPLICATIONS
`This application claims the benefit of United States Provisional Application
`Nos. 60/335,409, filed October 31, 2001; 60/356,703, filed February 13, 2002; and
`60/369,447, filed April 2, 2002, the disclosures of which are incorporated herein by
`reference.
`
`BACKGROUND OF THE INVENTION
`This invention relates in general to headlights that are provided on vehicles for
`illuminating dark road surfaces or other areas in the path of movement. In particular,
`this invention relates to an automatic directional control system for such vehicle
`headlights.
`Virtually all land vehicles, and many other types of vehicles (such as boats and
`airplanes, for example), are provided with one or more headlights that are adapted to
`illuminate a portion of a dark road surface or other area in the path of movement of the
`vehicle to facilitate safe travel thereon. Typically, each headlight is mounted on or
`near the front end of the vehicle and is oriented in such a manner that a beam of light
`is projected forwardly therefrom. The angle at which the beam of light projects from
`the headlight can, for example, be characterized in a variety of ways, including (1) up
`and down relative to a horizontal reference position or plane and (2) left and right
`relative to a vertical reference position or plane. Such directional aiming angles are
`usually set at the time of assembly of the headlight into the vehicle so as to illuminate
`a predetermined portion of the road surface or other area in the path of movement of
`the vehicle.
`In the past, these headlights have been mounted on the vehicle in fixed
`positions relative thereto such that the beams of light are projected therefrom at
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`predetermined directional aiming angles relative to the vehicle. Although such fixed
`aiming angle headlight systems have and continue to function adequately, they cannot
`alter the directional aiming angles of the headlights to account for changes in the
`operating conditions of the vehicle. For example, if the speed of the vehicle is
`increased, it would be desirable to adjust the aiming angle of the headlights upwardly
`such that an area that is somewhat farther in front of the vehicle is more brightly
`illuminated. On the other hand, if the speed of the vehicle is decreased, it would be
`desirable to adjust the aiming angle of the headlights downwardly such that an area
`that is somewhat closer in front of the vehicle is more brightly illuminated. Similarly,
`if the vehicle turns a corner, it would be desirable to adjust the aiming angle of the
`headlights either toward the left or toward the right (depending on the direction of the
`turn) such that an area that is somewhat lateral to the front of the vehicle is more
`brightly illuminated.
`To accomplish this, it is known to provide a directional control system for
`vehicle headlights that is capable of automatically altering the directional aiming
`angles of the headlights to account for changes in the operating conditions of the
`vehicle. A variety of such automatic directional control systems for vehicle headlights
`are known in the art. However, such known automatic headlight directional control
`systems have been found to be deficient for various reasons. Thus, it would be
`desirable to provide an improved structure for an automatic headlight directional
`control system that addresses such deficiencies.
`
`SUMMARY OF THE INVENTION
`This invention relates to an improved structure and method for operating a
`directional control system for vehicle headlights that is capable of automatically
`altering the directional aiming angles of the headlights to account for changes in the
`operating conditions of the vehicle. One or more operating condition sensors may be
`provided that generate signals that are representative of an operating condition of the
`vehicle, such as road speed, steering angle, pitch, suspension height, rate of change of
`road speed, rate of change of steering angle, rate of change of pitch, and rate of change
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`of suspension height of the vehicle. A controller is responsive to the sensor signal for
`generating an output signal. An actuator is adapted to be connected to the headlight to
`effect movement thereof in accordance with the output signal. The controller can
`include a table that relates values of sensed operating condition to values of the output
`signal. The controller is responsive to the sensor signal for looking up the output
`signal in the table.
`Various objects and advantages of this invention will become apparent to those
`skilled in the art from the following detailed description of the preferred embodiments,
`when read in light of the accompanying drawings.
`
`BRIEF DESCRIPTION OF THE DRAWINGS
`Fig. 1 is a block diagram of an automatic directional control system for a
`vehicle headlight in accordance with this invention.
`Fig. 2 is a flow chart of an algorithm for calibrating the automatic directional
`control system illustrated in Fig. 1 so as to define an initial reference position for the
`headlight from which the headlight directional controller can implement directional
`angle adjustments.
`Fig. 3 is a flow chart of an algorithm for generating a table that relates one or
`more sensed vehicle operating condition values to one or more headlight directional
`angle adjustment factors and for storing such table in the headlight directional
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`controller illustrated in Fig. 1.
`Fig. 4 is an example of a table that can be generated and stored in the headlight
`directional controller in accordance with the table generating algorithm illustrated in
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`Fig. 3.
`Fig. 5 is a flow chart of an algorithm for operating the headlight directional
`controller illustrated in Fig. 1 to automatically implement directional angle
`adjustments in accordance with sensed condition values.
`Fig. 6 is a flow chart of an algorithm for operating the headlight directional
`controller illustrated in Fig. 1 to automatically implement directional angle
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`adjustments in accordance with the rate of change of one or more of the sensed
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`condition values.
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`Fig. 7 is a flow chart of an algorithm for operating the headlight directional
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`controller illustrated in Fig. 1 to automatically implement directional angle
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`adjustments, but only when the rate of change of one or more of the sensed condition
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`values is less than (or greater than) a predetermined value.
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`DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
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`Referring now to the drawings, there is illustrated in Fig. 1 an automatic
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`directional control system, indicated generally at 10, for a vehicle headlight 11 in
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`accordance with this invention. The illustrated headlight 11 is, of itself, conventional
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`in the art and is intended to be representative of any device that can be supported on
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`any type of vehicle for the purpose of illuminating any area, such as an area in the path
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`of movement of the vehicle. The headlight 11 is typically mounted on or near the
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`front end of a vehicle (not shown) and is oriented in such a manner that a beam of
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`light is projected therefrom. In a manner that is well known in the art, the headlight 11
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`is adapted to illuminate a portion of a dark road surface or other area in the path of
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`movement of the vehicle to facilitate safe travel thereon.
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`The headlight 11 is adjustably mounted on the vehicle such that the directional
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`orientation at which the beam of light projects therefrom can be adjusted relative to the
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`vehicle. Any desired mounting structure can be provided to accomplish this.
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`Typically, the headlight 11 is mounted on the vehicle such that the angle at which the
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`beam of light projects therefrom can be adjusted both (1) up and down relative to a
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`horizontal reference position or plane and (2) left and right relative to a vertical
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`reference position or plane. Although this invention will be described and illustrated
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`in the context of a headlight that is adjustable in both the up/down direction and the
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`left/right direction, it will be appreciated that this invention may be practiced with any
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`headlight 11 that is adjustable in any single direction or multiple directions of
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`movement, whether up/down, left/right, or any other direction.
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`To effect movement of the illustrated headlight 11 relative to the vehicle, an
`up/down actuator 12 and a left/right actuator 13 are provided. The actuators 12 and 13
`are conventional in the art and may, for example, be embodied as servo motors, step
`motors, or any other electronically controlled mechanical actuators. It has been found
`to be desirable to use microstepping motors for the actuators 12 and 13. Such
`microstepping motors are known in the art and consist of conventional step motors
`that have appropriate hardware (i.e., driver integrated circuits) and software that allow
`the step motors to be operated in fractional step increments. The use of such
`microstepping motors has been found to be desirable because they can effect
`10 (cid:9) movements of the headlights in a somewhat faster, smoother, and quieter manner than
`conventional step motors, and further permit more precise positioning of the
`headlights 11. In the illustrated embodiment, the up/down actuator 12 is mechanically
`connected to the headlight 11 such that the headlight 11 can be selectively adjusted up
`and down relative to a horizontal reference position or plane. Similarly, the illustrated
`left/right actuator 13 is mechanically connected to the headlight 11 such that the
`headlight 11 can be selectively adjusted left and right relative to a vertical reference
`position or plane.
`A headlight directional controller 14 is provided for controlling the operations
`of the up/down actuator 12 and the left/right actuator 13 and, therefore, the angle at
`20 (cid:9) which the beam of light projects from the headlight 11 relative to the vehicle. The
`headlight directional controller 14 can be embodied as any control system, such as a
`microprocessor or programmable electronic controller, that is responsive to one or
`more sensed operating conditions of the vehicle for selectively operating the up/down
`actuator 12 and the left/right actuator 13. To accomplish this, the automatic
`directional control system 10 can include, for example, a pair of condition sensors 15
`and 16 that are connected to the headlight directional controller 14. The condition
`sensors 15 and 16 are conventional in the art and are responsive to respective sensed
`operating conditions of the vehicle for generating electrical signals to the headlight
`directional controller 14. However, if desired, only a single one of the condition
`sensors 15 and 16 need be provided. Alternatively, additional condition sensors (not
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`shown) may be provided if desired to generate electrical signals that are representative
`of any other operating conditions of the vehicle. A conventional input/output device
`17 is connected to (or can be connected to) the headlight directional controller 14 for
`facilitating communication therewith in the manner described below.
`If desired, a first position feedback sensor 18 may be provided for the up/down
`actuator 12, and a second position feedback sensor 19 may be provided for the
`left/right actuator 13. The position feedback sensors 18 and 19 are conventional in the
`art and are adapted to generate respective electrical signals that are representative of
`the actual up/down and left/right positions of the headlight 11. Thus, the first position
`feedback sensor 18 is responsive to the actual up/down position of the headlight 11 (as
`determined by a portion of the up/down actuator 12, for example) for generating an
`electrical signal to the headlight directional controller 14 that is representative thereof.
`Similarly, the second position feedback sensor 19 is responsive to the actual left/right
`position of the headlight 11 (as determined by a portion of the left/right actuator 13,
`for example) for generating an electrical signal to the headlight directional controller
`14 that is representative thereof. The position feedback sensors 18 and 19 can be
`embodied as any conventional sensor structures, such as Hall effect sensors, that are
`responsive to movements of the headlight 11 (or to the movements of the respective
`actuators 12 and 13 that are connected to move the headlight 1 1) for generating such
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`signals.
`Alternatively, the position feedback sensors 18 and 19 can be embodied as
`respective devices that generate electrical signals whenever the headlight 11 has
`achieved respective predetermined up/down or left/right positions. This can be
`accomplished, for example, using a conventional optical interrupter (not shown) for
`each of the actuators 12 and 13. Each of the optical interrupters includes a flag or
`other component that is mounted on or connected to the headlight 11 for movement
`therewith. Each of the optical interrupters further includes an optical source and
`sensor assembly. As the headlight 11 is moved by the actuators 12 and 13, the flag
`moves therewith relative to the optical source and sensor assembly between a first
`position, wherein the flag permits light emitted from the source from reaching the
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`sensor, and a second position, wherein the flag prevents light emitted from the source
`from reaching the sensor. When the flag is in the first position relative to the optical
`source and sensor assembly, the sensor is permitted to receive light emitted from the
`source. As a result, a first signal is generated from the optical source and sensor
`assembly to the headlight directional controller 14. Conversely, when the flag is in the
`second position relative to the optical source and sensor assembly, the sensor is not
`permitted to receive light emitted from the source. As a result, a second signal is
`generated from the optical source and sensor assembly to the headlight directional
`controller 14. Thus, the edge of the flag defines a transition between the first and
`second positions of the flag relative to the optical source and sensor assembly and,
`therefore, defines a predetermined up/down or left/right position of the headlight 11.
`The nature of the signal generated from the optical source and sensor assembly to the
`headlight directional controller 14 (i.e., the first signal or the second signal) can also
`be used to determine on which side of the predetermined position (the left side or the
`right side, for example) that the headlight 11 is positioned. The purpose for such
`position feedback sensors 18 and 19 will be discussed below.
`Fig. 2 is a flow chart of an algorithm, indicated generally at 20, for calibrating
`the automatic directional control system illustrated in Fig. 1 so as to define an initial
`reference position or positions for the headlight 11 from which the headlight
`directional controller 14 can implement directional angle adjustments. As mentioned
`above, the headlight 11 is mounted on the vehicle such that the angle at which the
`beam of light projects therefrom can be adjusted both up and down relative to a
`horizontal reference position or plane and left and right relative to a vertical reference
`position or plane. To insure accurate positioning of the headlight 11, it is desirable
`that a reference position or positions be initially established by the headlight
`directional controller 14. Subsequent directional angle adjustments can be made by
`the headlight directional controller 14 from the pre-established reference position or
`positions established by this calibration algorithm 20.
`To accomplish this, the calibration algorithm 20 has a first step 21 wherein the
`headlight directional controller 14 is caused to enter a calibration mode of operation.
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`In the calibration mode of operation, the headlight directional controller 14 is
`responsive to input signals from the input/output device 17 (or from another source, if
`desired) for causing manual operation of the up/down actuator 12 and the left/right
`actuator 13. Thus, while the headlight directional controller 14 is in the calibration
`5 (cid:9) mode of operation, an operator of the input/output device 17 can manually effect either
`up/down movement of the headlight 11, left/right movement of the headlight 11, or
`both, as desired.
`In a second step 22 of the calibration algorithm 20, the up/down actuator 12 and
`the left/right actuator 13 are manually operated to aim the headlight 11 in a
`predetermined reference orientation. This can be accomplished by use of the
`input/output device 17 that, as mentioned above, is connected to (or can be connected
`to) the headlight directional controller 14. Traditionally, the aiming of a headlight 11
`has been accomplished by parking the vehicle on a surface near a wall or other vertical
`structure, providing a reference target at a predetermined location on the wall or other
`structure, and mechanically adjusting the mounting structure of the headlight 11 such
`that the center of the beam therefrom is projected at the reference target. In this
`invention, the vehicle is parked on a surface near a wall or other vertical structure, and
`a reference target is provided at a predetermined location on the wall or other
`structure, as described above. Next, in accordance with the second step 22 of this
`calibration algorithm 20, the input/output device 17 is operated to generate electrical
`signals to the headlight directional controller 14. In response to such electrical signals,
`the headlight directional controller 14 operates the up/down actuator 12 and the
`left/right actuator 13 to move the headlight 11 such that center of the beam projecting
`therefrom is aimed at the reference target. When the beam from the headlight 11 is so
`aimed, then the headlight 11 is determined to be oriented in the initial reference
`position from which the headlight directional controller 14 can subsequently
`implement directional angle adjustments.
`In a third step 23 of the calibration algorithm 20, once this initial reference
`position for the headlight 11 has been achieved, such position is stored in the headlight
`directional controller 14 as the predetermined initial reference position. This can be
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`accomplished by means of the position feedback sensors 18 and 19. As discussed
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`above, the position feedback sensors 18 and 19 are adapted to generate respective
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`electrical signals that are representative of the actual up/down and left/right positions
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`of the headlight 11 or of the predetermined positions for the headlight. Thus, the first
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`position feedback sensor 18 is responsive to the actual up/down position of the
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`headlight 11 (as determined by the up/down actuator 12, for example) for generating
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`an electrical signal to the headlight directional controller 14 that is representative
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`thereof. Similarly, the second position feedback sensor 19 is responsive to the actual
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`left/right position of the headlight 11 (as determined by the left/right actuator 13, for
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`example) for generating an electrical signal to the headlight directional controller 14
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`that is representative thereof. Accordingly, the third step 23 of the calibration
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`algorithm 20 can be performed by causing the headlight directional controller 14 to
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`read the signals from the position feedback sensors 18 and 19 and store the current
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`up/down and left/right positions of the headlight 11 as the initial reference positions
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`from which the headlight directional controller 14 can subsequently implement
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`directional angle adjustments.
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`The current position of the headlight 11 is preferably stored in the non-volatile
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`memory of the headlight directional controller 14 for reference during normal
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`operation of the automatic directional control system 10 described below. Thus, when
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`20 (cid:9)
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`the automatic directional control system 10 is initially activated (such as when the
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`electrical system of the vehicle is initially turned on), the headlight directional
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`controller 14 can position the headlight 11 at or near the calibrated position utilizing
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`the signals comparing the current position of the headlight 11 (as determined by the
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`signals generated by the position feedback sensors 18 and 19) with the predetermined
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`25 (cid:9)
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`reference position determined by the calibration algorithm 20.
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`Fig. 3 is a flow chart of an algorithm, indicated generally at 30, for generating a
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`table that relates the sensed condition values from the condition sensors 15 and 16 to
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`the headlight directional angle adjustment factors that will be implemented by the
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`headlight directional controller 14, and further for storing such table in the headlight
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`30 (cid:9)
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`directional controller 14 illustrated in Fig. 1. As used herein, the term "table" is
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`intended to be representative of any collection or association of data that relates one or
`more of the sensed condition values to one or more of the headlight directional angle
`adjustment factors. The table of data can be generated, stored, and expressed in any
`desired format. For example, this table of data can be generated, stored, and expressed
`in a conventional spreadsheet format, such as shown in Fig. 4, which will be discussed
`in detail below.
`In a first step 31 of the table generating algorithm 30, an adjustment control
`algorithm is selected. The adjustment control algorithm can be, generally speaking,
`any desired relationship that relates one or more operating conditions of the vehicle to
`one or more angular orientations of the headlight 11. A variety of such relationships
`are known in the art, and this invention is not intended to be limited to any particular
`relationship. Typically, such relationships will be expressed in terms of a
`mathematical equation or similar relationship that can be readily processed using a
`microprocessor or similar electronic computing apparatus, such as the above-described
`headlight directional controller 14. The particular adjustment control algorithm that is
`selected may, if desired, vary from vehicle to vehicle in accordance with a variety of
`factors, including relative size and performance characteristics of the vehicle or any
`other desired condition.
`As mentioned above, a plurality of operating conditions may be sensed by the
`condition sensors 15 and 16 and provided to the headlight directional controller 14 for
`use with the adjustment control mechanism. For example, the condition sensors 15
`and 16 may generate electrical signals to the headlight directional controller 14 that are
`representative of the road speed, the steering angle, and the pitch of the vehicle (which
`can, for example, be determined by sensing the front and rear suspension heights of
`the vehicle or by a pitch or level sensor). Additionally, the time derivative of these
`operating conditions (i.e., the rate of change of the road speed, steering angle, and
`pitch of the vehicle) can be sensed or calculated. However, any other operating
`condition or conditions of the vehicle may be sensed and provided to the headlight
`directional controller 14.
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`In a second step 32 of the table generating algorithm 30, the table is generated
`using the adjustment control algorithm selected in the first step 31. The table can be
`generated in any desired manner. For example, let it be assumed that the selected
`adjustment control algorithm relates a single sensed operating condition to each of the
`angular adjustment control values for adjusting both the up/down orientation and the
`left/right orientation of the headlight 11. The table can be generated by initially
`selecting a first discrete sensed operating condition value that might be encountered
`during operation of the vehicle. Then, the selected adjustment control algorithm is
`solved using such first discrete sensed operating condition value to obtain the
`corresponding adjustment control values for the up/down and left/right orientation of
`the headlight 11. Then, the first discrete sensed operating condition value and the
`corresponding adjustment control values are stored in the table. This process can be
`repeated for any desired number of other discrete sensed operating condition values
`that might be encountered during operation of the vehicle.
`As mentioned above, Fig. 4 is a representative example of a table, indicated
`generally at 40, that can be generated in accordance with the second step 32 of the
`table generating algorithm 30 illustrated in Fig. 3. As shown therein, a series of
`discrete sensed operating condition values (degrees of steering angles, for example) is
`related to the angular adjustment control values (degrees of movement from the
`associated up/down and left/right reference positions or planes, for example) for
`adjusting both the up/down orientation and the left/right orientation of the headlight
`11. For the purposes of illustration only, let it be assumed that (1) a positive steering
`angle value represents steering toward left, while a negative steering angle value
`represents steering toward the right, (2) a positive up/down adjustment factor
`represents aiming the headlight 11 upwardly, while a negative up/down adjustment
`factor represents aiming the headlight 11 downwardly, and (3) a positive left/right
`adjustment factor represents aiming the headlight 11 toward the left, while a negative
`left/right adjustment factor represents aiming the headlight 11 toward the right.
`Thus, in accordance with the selected adjustment control algorithm, a sensed
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`30 (cid:9)
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`steering angle of -1-6° results in an up/down adjustment factor of -3.00° and a left/right
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