LASER GUIDED PARKING ASSISTANCE DEVICE

Abstract

A laser guided parking assistance device and methods of operation are disclosed. An example laser guided parking assistance device includes a tilt switch to detect a vertical orientation of a horizontal orientation. The laser guided parking assistance device also includes a laser to emit a laser light beam in response to the tilt switch detecting the horizontal orientation. In an example, a laser guided parking assistance device is configured as a circuit including a battery power source, a laser diode connected in series with the battery power source, and a first tilt switch connected between the battery power source and the laser diode. The tilt switch opens in a vertical position to cut electrical power from the battery power source to the laser diode The first tilt switch closes in a horizontal position to connect electrical power from the battery power source to the laser diode.

Description

BACKGROUND

In most residential garages, the parking area is tight. Vehicles have to be parked at the correct position inside of the garage to leave enough area in front and back of the vehicle to enable the driver and/or passengers to enter and exit the vehicle. Various parking guides are commercially available for assisting a driver to park a vehicle inside a garage at the desired position.

An example is a laser mounted to the ceiling of the garage which casts a laser light dot onto the dashboard of a vehicle as a position reference for assisting the driver to park the vehicle at a desired position. Typically, a motion detector (e.g., detecting motion of the vehicle, or the garage door) is used to trigger operation of the laser. Alternately, the operation of the laser may be triggered by operation of the garage door opener.

Installation and maintenance of these laser guides onto the ceiling of the garage can be difficult. In addition, the sensing mechanism which actuates the laser must operate continuously (e.g., 24 hours per day, 7 days per week), even though the laser guiding function may only be used a couple of times a day for a few minutes each time. Therefore, these laser guides typically require access to the household electric (e.g., installation near an existing outlet or installation of additional electrical wiring).

The sensing mechanism can be affected by various environmental and external interferences. For example, infrared (IR) motion detection can be affected by environmental conditions (e.g., dust, spider webs, temperature), and even the height of the garage ceiling. Sensing mechanisms that trigger based on light being emitted from the light bulb of the garage door opener (e.g., to indicate operation of the garage door opener) depend on the light bulb performing properly.

Furthermore, the laser may be actuated unintentionally and may cause harm For example, pets or children may pass thru the area and actuate the laser. The laser beam may be attractive to pets or children, who may look into the laser and result in short term or even long term pain or even eye damage.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a garage with a closed garage door (in a vertical position) with an example laser guided parking assistance device mounted at the top of the garage door.

FIG. 2 illustrates a garage with an open garage door (in a horizontal position near the garage ceiling) with the example laser guided parking assistance device mounted on the top of the garage door shining a laser light beam onto the windshield of a vehicle.

FIG. 3 illustrates the vehicle moving through different positions in the garage, and reflecting a laser light dot from the example laser guided parking assistance device onto the wall in front of the vehicle.

FIG. 4 is a circuit diagram of an example laser guided parking assistance device.

FIG. 5 is a circuit diagram of another example laser guided parking assistance device with a time delay circuit to turn off the laser if the garage door is left in an open position.

FIG. 6 is a circuit diagram of another example laser guided parking assistance device with a solar battery to provide electrical power.

DETAILED DESCRIPTION

A laser guided parking assistance device and method of operation is disclosed. An example laser guided parking assistance device deploys an eye safe laser for assisting vehicle operators to park a vehicle at the desired position.

In art example, the laser guided parking assistance device can be installed at a more accessible place than a ceiling of the garage (e.g., on the garage door itself), making installation and maintenance or removal easy and convenient. For example, the laser guided parking assistance device can be mounted by an attachment (e.g., screws) to attach the laser guided parking assistance device to a strut on a top panel of the garage door. In an example, the attachment can be implemented without needing tools (e.g., as a clamp or double-sided tape).

An example laser guided parking assistance device reduces electrical power consumption when the device is not in use, even down to zero power consumption. The lower power consumption also enables operation by battery power.

In an example, the laser guided parking assistance device includes a tilt switch, a battery, and an electronic circuit. When the garage door is closed, the laser guided parking assistance device is in a vertical position. When the garage door is open, the laser guided parking assistance device is in a horizontal position near the garage ceiling. The tilt switch inside the device is arranged in the way that when the garage door is in the vertical position the tilt switch is opened and when the garage door is in the horizontal position the tilt switch is closed. When the tilt switch is open, the switch cuts off battery power to all of the electronics of the laser guided parking assistance device so that the device does not consumes electrical power. When the tilt switch is closed, the switch connects electrical power to the electronics of the device which turns on the laser for guiding vehicle parking.

The tilt switch also enables a sensing function that is free of environmental and external interference, thereby increasing reliability of the laser guided parking assistance device. In addition, the laser is not activated by movement of pets or people, improving safety.

When the laser is tuned on by the garage door having reached the horizontal position near the garage ceiling, the laser shines a light beam down to the garage floor. As a vehicle moves into the garage, the laser beam shines onto the hood of the vehicle and casts a laser light dot onto the hood. As the vehicle continues to travel into the garage, the laser beam shines onto the windshield of the vehicle.

In an example, the laser guided parking assistance device is mounted at a position on the garage door such that the laser beam is shining onto the windshield slightly at an angle behind the windshield when the vehicle is reaching the desired position. This configuration causes the laser beam to be split into two laser beams by the glass of the windshield. One laser beam shines through the windshield and casts a laser light dot onto the dashboard of the vehicle. The other laser beam is deflected off of the windshield glass and casts a laser light dot onto a wall in front of the vehicle. When the vehicle is traveling to different positions, both laser light dots move to different locations. The driver can monitor either or both of the laser light dots as position references to park the vehicle at a desired position.

In an example, the laser can also be turned off by a time delay circuit when the garage door is kept in an open position. The quiescent electronic current in this state is the leaking current of the electronic components in the circuit, which is typically no more than a few micro amps for most commercial electronic components. Normal household batteries can hold power at this low level leaking current for years. The time delay circuit is reset when the garage door is closed.

Before continuing, it is noted that as used herein, the terms “includes” and “including” mean, but is not limited to, “includes” or “including” and “includes at least” or “including at least.” The term “based on” means “based on” and “based at least in part on.”

FIG. 1 illustrates a garage 1 with a closed garage door 2 (in a vertical position) with an example laser guided parking assistance device 10 mounted at the top of the garage door 2. The garage door 2 can move along the tracks 3 and 4.

In an example, the laser guided parking assistance device 10 includes an orientation switch, such as a tilt switch. The tilt switch may be gravity actuated. That is, the tilt switch operates based on its orientation as determined by gravitational pull. The tilt switch may be arranged such that it is open (no electrical current flow) when the garage door 2 is in a vertical position, and the tilt switch is closed (electrical current flow) when the garage door 2 is in a horizontal position. In FIG. 1, the garage door 2 is shown closed and as such the tilt switch is in the vertical position and the tilt switch is open. Power is turned off, and as such the laser is turned off.

FIG. 2 illustrates the garage 1 with an open garage door 2 (in a horizontal position near the garage ceiling) with the example laser guided parking assistance device 10 mounted on or near the top of the garage door. With the garage door 2 in the horizontal position, the tilt switch is closed and the electronic circuit of the laser guided parking assistance device 10 is powered on.

In an example, the laser guided parking assistance device 10 is powered by a battery. The battery is sized sufficient to actuate a laser diode which generates a laser beam 20. The laser beam 20 emits downward in the direction of the garage floor 5.

In an example, the laser guided parking assistance device 10 is mounted in a position on the garage door 2 such that the laser beam 20 is emitted at an angle selected to be a behind the windshield 6 of the vehicle 7 when the vehicle 7 is moving close to the desired parking position, it is understood that this angle can be adjusted for a generic vehicle and/or determined based on the specific configuration of the vehicle being operated (e.g., including vehicle height and angle of the windshield).

When the laser beam 20 hits the windshield 6 of the vehicle 7, the laser beam 20 is split by the glass of the windshield 6, and forms two beams 21a and 22a. Light beam 21a transmits through the windshield 6 and casts a laser light dot 21b onto the dashboard 8 of the vehicle 7. The laser beam 22a is deflected off of the windshield 6 and casts a laser light dot 22b onto the wall 9 in front of the vehicle 7. Accordingly, the driver (or passenger) can visually observe the position of the vehicle 7 relative to a desired parking area within the garage 1.

FIG. 3 illustrates the vehicle 7 moving through different positions in the garage 1 and reflecting a laser light dot from the example laser guided parking assistance device 10 onto the all 9 in front of the vehicle 7.

In the example shown in FIG. 3, the vehicle 7 is shown moving from a position 30 to a position 31. For the position 30 of the vehicle 7, the deflected laser beam is illustrated by line 22a and the laser light dot is shown at 22b. For the position 31 of the vehicle 7, the deflected laser beam is illustrated by line 22c and the laser light dot is shown at 22d. At the same time that the user sees dots moving on the wall from 22b to 22d, the laser light dot 21b on the dashboard 8 of the vehicle also moves (not shown) to a new position on the dashboard 8.

In an example, marking can be provided by the manufacturer of the laser guided parking assistance device 10 to affix to the wall 9 and/or the dashboard 8 of the vehicle 7. In another example, the driver may provide his or her own markings and/or simply remember the relative position of the dots with respect to the desired parking alignment.

Before continuing, it should be noted that the examples described above are provided for purposes of illustration, and are not intended to be limiting. Other devices and/or device configurations may be utilized to carry out the operations described herein.

By way of non-limiting example, the orientation of the switch may be reversed and the circuit wired accordingly. In another example, multiple lights may be provided and/or the position of the lights may vary. Likewise, the light source is not limited to a laser and can be any suitable light source (e.g., LED lighting). These and other variations will be readily understood by those having ordinary skill in the art after becoming familiar with the teachings herein.

FIG. 4 is a diagram of an example circuit 100 to implement the laser guided parking assistance device. In an example, the circuit has only four components, simplifying the circuit, minimizing cost, and improving reliability. However, the circuit is not limited to any particular number of components.

In an example, the circuit 100 includes a battery 110 to provide electrical power. The circuit 100 also includes a tilt switch 120 to turn power on and off in the circuit The tilt switch 110 may be opened or closed based on orientation of the switch. The circuit 100 also includes a laser diode 130 to generate and emit a laser beam. The circuit may also include a resistor 140 to set the electrical current flowing through the laser diode 130 and determines the output or brightness of the laser beam.

FIG. 6 is a diagram of another example circuit 200 to implement the laser guided parking assistance device, in an example, the circuit 200 includes a battery 210 to provide electrical power. The circuit 200 also includes a tilt switch 220 to turn power on and off in the circuit. The tilt switch 220 may be opened or closed based on orientation of the switch. The circuit 200 also includes a laser diode 230 to generate and emit a laser beam. The circuit may also include a resistor 240 to set the electrical current flowing through the laser diode 230 and determines the output or brightness of the laser beam.

In addition, the example circuit 200 shown in FIG. 5 implements a voltage regulator 250 to provide a regulated voltage to drive the laser diode 230. As such, the brightness of the laser light is not affected by the battery voltage change over the time due to discharge, as long as the battery is still capable of providing an operating power for the laser diode 230.

In addition, the example circuit 200 shown in FIG. 5 includes a time delay circuit to turn off the laser if the garage door is left in an open position. The time delay circuit may be implemented as an R-C time delay circuit including resistor 260 and capacitor 270. If the garage door is left open, the capacitor 270 is charged through resistor 260. When the voltage on capacitor 270 reaches a predetermined level, it turns off the MOSFET switch 280 and therefore turns off the laser diode 230. When the MOSFET switch 280 is turned off, the quiescent current of the circuit is the leaking currents of the MOSFET switch 280 and the capacitor 270. These are typically only a few micro amps for most available commercial products. Discharging at this rate, a standard AA battery can last for years.

In addition, the example circuit 200 shown in FIG. 5 may include a second tilt switch 290. Tilt switch 290 provides a quick discharge path for capacitor 270 when the garage door is closed. As such, the circuit 200 is ready to turn on the laser diode 230 again without delay after the garage door has been closed. In an example, the second tilt switch 290 is physically arranged in a perpendicular orientation relative to the tilt switch 220. As such, the tilt switch 220 is closed when the garage door is closed, and the tilt switch 220 is open when the garage door is open. It is noted that the physical orientation of the switches 220 and 290 is not illustrated by the circuit diagram.

FIG. 6 is a diagram of another example circuit 300 to implement the laser guided parking assistance device. In an example, the circuit 300 includes a battery 310 to provide electrical power. The circuit 300 also includes a tilt switch 320 to turn power on and off in the circuit. The tilt switch 310 may be opened or closed based on orientation of the switch. The circuit 300 also includes a laser diode 330 to generate and emit a laser beam. The circuit may also include a resistor 340 to set the electrical current flowing through the laser diode 330 and determines the output or brightness of the laser beam.

In addition, the example circuit 300 shown in FIG. 6 implements a voltage regulator 350 to provide a regulated voltage to drive the laser diode 330. As such, the brightness of the laser light is not affected by the battery voltage change over the time due to discharge, as long as the battery is still capable of providing an operating power for the laser diode 330.

In addition, the example circuit 300 shown in FIG. 6 includes a time delay circuit to turn off the laser if the garage door is left in an open position. The time delay circuit may be implemented as an R-C time delay circuit including resistor 360 and capacitor 370. If the garage door is left open, the capacitor 370 is charged through resistor 360. When the voltage on capacitor 370 reaches a predetermined level, it turns off the MOSFET switch 380 and therefore turns off the laser diode 330. When the MOSFET switch 380 is turned off, the quiescent current of the circuit is the leaking currents of the MOSFET switch 380 and the capacitor 370. These are typically only a few micro amps for most available commercial products. Discharging at this rate, a standard AA battery can last for years.

In addition, the example circuit 300 shown in FIG. 6 may include a second tilt switch 390. Tilt switch 390 provides a quick discharge path for capacitor 370 when the garage door is closed As such, the circuit 300 is ready to turn on the laser diode 330 again without delay after the garage door has been closed. In an example, the second tilt switch 390 is physically arranged in a perpendicular orientation relative to the tilt switch 320. As such, the tilt switch 390 is dosed when the garage door is dosed, and the tilt switch 390 is open when the garage door is open. It is noted that the physical orientation of the switches 320 and 390 is not illustrated by the circuit diagram.

In FIG. 6, the circuit 300 is also shown including a solar battery 390 to provide electrical power. In an example, the solar battery 390 can be mounted on the window of the garage door, or the solar battery can be mounted on the outer side of the garage door. For example, if the garage door does not have glass windows, the solar battery can be installed on the outer side of the garage door. The solar battery 390 can be implemented in parallel with a standard battery 310, or by itself. When implemented as shown in the circuit diagram of FIG. 6, diodes 391 and 392 may also be provided.

The example circuits 100, 200, and 300 shown and described herein are provided only for purposes of illustration and are not intended to be limiting. Other circuits (simple or more sophisticated) may be implemented, as will be readily understood by those having ordinary skill in the art after becoming familiar with the teaching herein.

It is noted that the examples shown and described are provided for purposes of illustration and are not intended to be limiting. Still other examples are also contemplated.

Claims

1. A laser guided parking assistance device, comprising: a tilt switch to detect a vertical orientation of a horizontal orientation; anda laser to emit a laser light beam in response to the tilt switch detecting the horizontal orientation.

2. The laser guided parking assistance device of claim 1, wherein the tilt switch is gravity sensing.

3. The laser guided parking assistance device of claim 1, further comprising a body housing the tilt switch and the laser

4. The laser guided parking assistance device of claim 3, further comprising an attachment to attach the body to a garage door.

5. The laser guided parking assistance device of claim 1, wherein the laser is positioned at an angle to shine a laser beam onto a windshield of a vehicle as the vehicle is reaching a desired parking position, thereby splitting the laser beam into two laser beams.

6. The laser guided parking assistance device of claim 5, wherein one of the two laser beams shines through the windshield and casts a laser light dot onto a dashboard of the vehicle.

7. The laser guided parking assistance device of claim 5, wherein one of the two laser beams is deflected off of the windshield and casts a laser light dot onto a wall in front of the vehicle.

8. The laser guided parking assistance device of claim 5, wherein two laser light dots move to different locations as the vehicle travels to different positions, and wherein a driver monitors either or both of the laser light dots as position references to park the vehicle at a desired position.

9. The laser guided parking assistance device of claim 1, further comprising a time delay circuit to turn off the laser when a garage door is kept in an open position.

10. The laser guided parking assistance device of claim 1, further comprising a battery providing power to the laser without need for a household electric source.

11. A laser guided parking assistance device, comprising: a battery power source;a laser diode connected in series with the battery power source; anda first tilt switch connected between the battery power source and the laser diode, the tilt switch opening in a vertical position to cut electrical power from the battery power source to the laser diode, the first tilt switch closing in a horizontal position to connect electrical power from the battery power source to the laser diode.

12. The laser guided parking assistance device of claim 11, further comprising a resistor in series with the laser diode, the resistor setting electrical current to the laser diode to determine brightness of a laser beam generated by the laser diode.

13. The laser guided parking assistance device of claim 11 further comprising a voltage regular to provide a regulated voltage to drive the laser diode, to maintain a substantially constant light output even as the battery power source declines in power output.

14. The laser guided parking device of claim 11, further comprising a time delay circuit.

15. The laser guided parking assistance device of claim 14, wherein the time delay circuit is a resistor-capacitor circuit, wherein a capacitor charges through a resistor when a garage door is left open, and when a voltage on the capacitor reaches a predetermined level, a mosfet switches to turn off the laser diode.

16. The laser guided parking assistance device of claim 15, further comprising a second tilt switch providing a quick discharge path for the capacitor when the garage door is closed.

17. The laser guided parking assistance device of claim 16, wherein the second tilt switch is perpendicular to the first tilt switch so that the second tilt switch is closed when the garage door is closed, and the second tilt switch is open when the garage door is open.

18. The laser guided parking assistance device of claim 11, wherein the battery power source is a solar battery.

19. A method of operating laser guided parking assistance device, comprising: detecting by a tilt switch, a vertical orientation of a horizontal orientation of a garage door; andemitting a laser ht beam in response to the tilt switch detecting the horizontal orientation.

20. The method of claim 19, further comprising the tilt switch opening in a vertical position to cut electrical power to a laser diode emitting the laser light beam, and the tilt switch closing in a horizontal position to power the laser diode.