EMERGENCY CENTER HIGH MOUNTED STOP LAMP (CHMSL) CONTROLLER

Abstract

An improved Center High Mounted Stop Lamp (CHMSL) harvests electrical power while providing additional features when the CHMSL is not powered during a brake application. Electronic circuitry determines if the different sources of electrical power have sufficient energy to activate the light-emitting device; senses a vehicle braking or emergency event to activate the light-emitting device upon sensing the event; and switches from one source of electrical power to a different source of electrical power if it is determined that a particular source of electrical power has become depleted or incapable of activating the light-emitting device. The different sources of electrical power may include a supercapacitor, a rechargeable battery, or a primary battery. The electronic circuitry operative to sense a braking or emergency event may include a brake signal input or an inertial measurement unit (IMU).

Claims

1. A vehicular lighting system, comprising: a housing configured for center high mounting on the rear of a passenger vehicle; at least one light-emitting device; power source charge management circuitry disposed in the housing, the power source charge management circuitry comprising a plurality of inputs and a power output in electrical communication with the light-emitting device, each input to the power source charge management circuitry being associated with a different source of electrical power, the different sources of electrical power at least including a supercapacitor, a rechargeable battery, or both a supercapacitor and a rechargeable battery; wherein the power source charge management circuitry includes one or more electrically controlled switches operative to route the different sources of electrical power to the power output and to the light-emitting device; and electronic circuitry disposed in the housing operative to perform the following functions: (a) determine if the different sources of electrical power have sufficient energy to activate the light-emitting device; (b) sense a vehicle braking or emergency event and activate the light-emitting device upon sensing the event; and (c) send an electrical signal to the power source charge management circuitry, causing the one or more electrically controlled switches to switch from one source of electrical power to a different source of electrical power if it is determined that a particular source of electrical power has become depleted or incapable of activating the light-emitting device.

2. The lighting system of claim 1, wherein the supercapacitor is charged by vehicle brake application.

3. The lighting system of claim 1, wherein the rechargeable battery is recharged by the supercapacitor.

4. The lighting system of claim 1, wherein one of the different sources of electrical power is derived from a permanent battery used to start or power the vehicle.

5. The lighting system of claim 1, wherein the at least one light-emitting device is disposed on or in the housing.

6. The lighting system of claim 1, wherein the electronic circuitry operative to sense a braking or emergency event includes an inertial measurement unit (IMU).

7. The lighting system of claim 6, wherein the IMU is operative to sense a collision along a forward-reverse axis of the vehicle.

8. The lighting system of claim 6, wherein the IMU is operative to sense a spinout along a driver-passenger axis of the vehicle.

9. The lighting system of claim 6, wherein the IMU is operative to sense a rollover vehicle accident along any axis using rotational sensing.

10. The lighting system of claim 1, wherein the electronic circuitry operative to sense an emergency or braking event includes an input from a vehicle braking system.

11. The lighting system of claim 1, further including a boost converter operative to increase the operating voltage of a power source if the voltage of the source falls below a predetermined voltage required to operate the light-emitting device.

12. The lighting system of claim 1, wherein the electronic circuitry is operative to alter a frequency or duty cycle of the at least one light-emitting device.

13. The lighting system of claim 1, wherein the at least one light-emitting device is a multi-color light-emitting diode (LED), LED, and wherein the electronic circuitry is operative to alter the color of the LED to indicate different emergency events or levels of severity.

14. A vehicular lighting system, comprising: a housing configured for center high mounting on the rear of a passenger vehicle; at least one light-emitting device; a plurality of inputs, each input being associated with a different source of electrical power; electronic circuitry disposed in the housing operative to perform the following functions: (a) determine if the different sources of electrical power have sufficient energy to activate the light-emitting device; (b) sense a vehicle braking or emergency event and activate the light-emitting device upon sensing the event; and (b) switch from one source of electrical power to a different source of electrical power if it is determined that a particular source of electrical power has become depleted or incapable of activating the light-emitting device; wherein the electronic circuitry operative to sense a braking or emergency event includes an inertial measurement unit (IMU), and wherein the IMU is operative to sense the following types of accidents: a collision along a forward-reverse axis of the vehicle, a spinout along a driver-passenger axis of the vehicle, and a rollover vehicle accident along any axis using rotational sensing.

15. The lighting system of claim 14, wherein one of the different sources of electrical power is a supercapacitor.

16. The lighting system of claim 14, wherein one of the different sources of electrical power is a rechargeable battery.

17. The lighting system of claim 14, wherein one of the different sources of electrical power is a permanent battery used to start or power the vehicle.

18. The lighting system of claim 14, wherein the at least one light-emitting device is disposed on or in the housing.

19. The lighting system of claim 14, wherein the electronic circuitry is operative to alter a frequency or duty cycle of the at least one light-emitting device.

20. The lighting system of claim 14, wherein the light-emitting device is a multi-color LED, and the electronic circuitry is operative to alter the color of the LED during an emergency situation.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] FIG. 1 is block diagram of a preferred embodiment of the invention showing various functional modules.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0014] FIG. 1 is block diagram of a preferred embodiment of the invention showing various functional modules. The various components are disposed in a housing 102 which may be situated internal to a vehicle or mounted on a portion of the exterior. If disposed within the vehicle, CHMSL lights 100 would be in a separate, high-mounted outside enclosure. If housing 102 is outside-mounted, CHMSL lights would be integrated into the enclosure 102. Although any type of CHMSL lights 100 may be used, high-brightness light-emitting diodes are preferred, and all enclosures used are preferably sealed off from the ambient environment.

[0015] Overall control is provided by a central-processing unit (CPU) 118 such as an ATMEL (ATMEGA family) or PIC16F family of conventional CPUs, or a proprietary designed ASIC with integrated CPU. The device 118 is preferably a single-chip microcomputer including on-board memory including programmed instructions to carry out at least the functions disclosed herein. One of skill in the art will understand how software would be written to provide these programmed instructions. The CPU 118, as well as the other circuits to be described, may be selected to operate in the automotive temperature range; namely, −40° C. to 125° C.

[0016] Electronics in the unit may be powered via one to four power sources with a switching function provide by source charge manager 110 to control input. The first power source 104 is accomplished using a supercapacitor (SC) to rapidly charge during a traditional brake application. Energy from the SC can be used to recharge the second power input, battery 106, or to power the CHMSL during an ‘unpowered’ event. The battery is preferably a Lithium Polymer battery (LiPo), though other types of batteries may alternatively be used due to the need to operate in the automotive temperature range. While the SC and rechargeable battery are shown external to housing 102, in the preferred embodiment these components are disposed within housing 102.

[0017] The third power source is a permanent battery 108 that can be used should the SC and the LiPo become completely depleted. For example, the vehicle's 12-volt battery may be used, or other auxiliary source may be used, particularly if the vehicle is an electric or hybrid vehicle.

[0018] Source charge manager 110 is preferably implemented with solid-state switches such as power field-effect transistors or, alternatively, relays or mechanical switches may be used. Power routing in controlled by CPU 118, first choosing SC source 104. That source is sensed as depleted, (i.e., by measuring voltage levels and current capacity against the source profile by the CPU 118), the CPU instead chooses LiPo source 106 and, if that source is or becomes depleted, the permanent battery source 108 is selected. A ‘Boost Converter’ 112 is used to extend functionality should the operating voltage of the SC, LiPo,

[0019] Inertia Measurement Unit (IMU) 116 is used to sense emergency events such as a collision along the forward reverse axis, a spinout along the driver-passenger axis, or a rollover along any axis using the rotational sensing of the IMU as available in the BM160 by Bosch or the ICM-20608 from STMicroelectronics. This device also can determine if the vehicle is operating in a driving situation normally to cancel the emergency event.

[0020] The GPIO/UART 120 is used to interface via connection 122 to other vehicle electronics over commonly used automotive busses (i.e., CAN/LIN), for receiving constant or switched power from the vehicle battery, or for sensing control functions such as ‘hazard lights, turn signals, or reverse.’ In the event the GPIO is wired to the vehicle battery, the SC, LiPo, and permanent batteries may be used as ‘back up’ power sources to the vehicle's main power supply which may become inoperable during a collision. Outputs from the GPIO/UART can be configured to also drive other external loads (i.e., exterior lighting illuminates during loss of vehicle battery) that could be important to drive during an emergency event.

[0021] The system may include some or all of the functional modules listed below. The word “may” is used here since different embodiments of the invention may not include all of the modules described. Indeed, the system is intended to be modular enabling the various capabilities to mixed-and-matched for different applications or types of vehicles. These modules may include the following, without limitation: [0022] IMU (Inertia Measurement Unit); [0023] Permanent Battery; [0024] Rechargeable Battery; [0025] Supercapacitor; [0026] GPIO (General Purpose Input/Output Interface); and [0027] Vehicle Interface.

[0028] The functions afforded by each of the subsystems are described in detail below.

[0029] Generally speaking, the CHMSL system described herein includes some of the features found with factory-installed CHMSLs, while providing several additional capabilities. For example, the system senses when the vehicle is in a collision via either UART 120 and/or via IMU 116 to determine that a collision event has occurred. This may be accomplished either by sensing excessive force, or by sensing an accident indicator such as ‘airbags deployed’ from the vehicle system.

[0030] The system may also generate a warning pattern on the CHMSL an emergency event is sensed from the IMU. This visual warning indicator can be of any pattern, duty cycle, or duration. For example, brake input line 124 may be used to sense a conventional braking function, and/or this input may be used as a trigger from the driver in an medical emergency, or if they are being car-jacked.

[0031] The Vehicle Interface 122 is designed to contain common electrical signals used in most vehicles on the road today. These may include, without limitation, battery power, ground, LIN/CAN communication, and outputs for triggering vehicle loads such as lighting and accessory relays or door, window, trunk, liftgate latch relays, etc. Alternatively, the Vehicle Interface 122 may be simplified to include only battery power upon brake activation, which employs the energy harvesting function of the invention.

[0032] Energy harvesting is accomplished when external power is applied during a normal braking event from power applied to the system via 124. SCs (104) are charged at a high rate and discharged to charge the LiPo ((106) in the event the LiPo is not fully charged. In the event the LiPo is fully charged, energy from the SC is used to power an emergency event as well as to power the CPU and IMU to monitor for an emergency event. The CPU will enter a low-power mode to eliminate any current draw while there is no movement on the vehicle.

[0033] If an emergency event is triggered, the system will perform a visual emergency indicator either until all three power sources are depleted or a predetermined timer expires, or the vehicle is moved at an inertia substantially below the triggering inertia, or a normal braking signal is applied for a predetermined number of applications.

[0034] Further, warning functions can be implemented during normal braking events such as (1) a moderately oscillating (i.e 2-5 Hz) flashing light during the braking event if the vehicle is slowing down but has not yet stopped, or (2) a more rapidly (i.e., 5-10 Hz) oscillating flashing light during a more aggressive braking event. Flashing of the light would cease and return to constant-on when the vehicle returned to a stopped or very slow speed as calibrated.

[0035] To conserve power during an emergency event, as the available energy sources begin to deplete, CPU 118 can alter the frequency and duty cycle of the load switching to extend the usefulness of the available power source while maintaining desired illumination levels. Visual Emergency indicators may also change color using commonly used RGB LEDs to represent different emergency events of different severity. For example, from yellow to red to indicate increased severity.