ELECTRONIC VEHICLE ACCESS CONTROL SYSTEM

Abstract

A vehicle door includes a powered latch mechanism and an interior door handle having first and second sensors disposed on opposite sides of the interior door handle. The first and second sensors are configured to detect the presence of a user's hand to control operation of the powered latch mechanism. The powered latch may be unlatched if an unlatch switch is actuated and the first and second sensors detect the presence of a user's hand.

Description

FIELD OF THE INVENTION

The present invention generally relates to doors for motor vehicles, and more particularly, to a door handle having sensors and/or switches that may be utilized to control operation of a powered door latch.

BACKGROUND OF THE INVENTION

Conventional door latches typically include a “claw” that engages a striker to retain the door in a closed position. A pawl selectively retains the claw in an engaged position to prevent the vehicle from opening. The pawl is typically mechanically connected to interior and exterior door handles whereby movement of the handles unlatches the latch by shifting the pawl to a released (unlatched) position, thereby permitting the claw to move and disengage from the striker.

Powered door latches (“e-latches”) have also been developed. Powered door latches may be unlatched by actuating an electrical “unlatch” switch. Actuation of the unlatch switch causes an electric motor to shift a pawl of the powered latch mechanism to a released (unlatched) position that allows the “claw” to release from a striker. However, known e-latch arrangements may suffer from various drawbacks such as unintentional or accidental trigger of the release switch by the customer.

SUMMARY OF THE INVENTION

One aspect of the present invention is a vehicle door including a door structure having an interior surface. The vehicle door also includes a powered latch mechanism that can be actuated to shift from a latched configuration to an unlatched configuration. An interior door handle is disposed on the door structure. The handle includes a graspable portion that is spaced apart from the interior surface of the door structure to define a gap. The graspable portion of the interior door handle has a first side that generally faces the interior surface, and a second side that generally faces away from the interior surface. First sensors are disposed on the first side of the graspable portion. The first sensors are configured to detect the presence of a user's hand. Second sensors on the second side of the graspable portion are configured to detect the presence of a user's hand. The vehicle door further includes an unlatch switch on the door structure. The powered latch mechanism does not unlatch unless the unlatch switch is actuated when the first and second sensors also detect the presence of a user's hand.

Another aspect of the present invention is a vehicle door including a door structure and an elongated interior door handle having capacitive sensors disposed on opposite sides thereof. A manually actuated switch is disposed at an end of the elongated interior door handle. The vehicle door also includes a powered latch and a controller that is configured to unlatch the powered latch if the capacitive sensors detect a hand on the opposite sides of the handle, and if the switch is actuated within a predefined time interval of detecting a hand.

Another aspect of the present invention is a method of controlling a powered door latch of a vehicle. The method includes providing a door structure having an interior handle and a powered latch configured to selectively retain the door in a closed position. Sensors are provided on opposite sides of the interior handle, and the powered latch is unlatched only if the sensors on opposite sides of the handle detect a user's hand. The door may include a switch, and the powered latch may be unlatched only if the switch is actuated within a predefined time interval of detection of a user's hand by the sensors.

These and other aspects, objects, and features of the present invention will be understood and appreciated by those skilled in the art upon studying the following specification, claims, and appended drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings:

FIG. 1 is a partially schematic view of a vehicle door having an interior handle and powered latch according to one aspect of the present invention;

FIG. 2 is a schematic drawing of a powered latch;

FIG. 3 is a fragmentary cross sectional view taken along the line II-II; FIG. 1;

FIG. 4 is a fragmentary cross sectional view taken along the line FIG. 1;

FIG. 5 is an electrical diagram of the door handle and powered latch of FIG. 1; and

FIG. 6 is a flow chart showing operation of the door handle and powered latch.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

For purposes of description herein, the terms “upper,” “lower,” “right,” “left,” “rear,” “front,” “vertical,” “horizontal,” and derivatives thereof shall relate to the invention as oriented in FIG. 1. However, it is to be understood that the invention may assume various alternative orientations, except where expressly specified to the contrary. It is also to be understood that the specific devices and processes illustrated in the attached drawings, and described in the following specification are simply exemplary embodiments of the inventive concepts defined in the appended claims. Hence, specific dimensions and other physical characteristics relating to the embodiments disclosed herein are not to be considered as limiting, unless the claims expressly state otherwise.

With reference to FIG. 1, a vehicle door 1 includes a door structure 2 that may be movably mounted to a primary vehicle structure by hinges 4A and 4B in a known manner. The vehicle door 1 may include a powered latch 6 that is operably connected to a controller 8. It will be understood that controller 8 may comprise one or more programmable controllers, circuits, or other suitable devices. For example, controller 8 may comprise a controller that is integrated into powered latch 6, and controller 8 may further include other controllers that are integrated into the vehicle. Further, controller 8 may comprise a vehicle wide network and able to communicate with other powered latches 6 of additional doors. The vehicle wide network may include modules and/or sensors that provide data concerning various vehicle operating parameters such as vehicle speed, ignition switch status, and notification of a crash event in progress.

With further reference to FIG. 2, powered latch 6 may include a claw 80 that pivots about a pin 82. In use, when door 1 is open, claw 80 will typically be in an extended position 80A. As the door 1 is closed, surface 90 of claw 80 comes into contact with a striker 84 that is mounted to the vehicle structure. Contact between striker 84 and surface 90 of claw 80 causes the claw 80 to rotate about pin 82 in the direction of the arrow “R1” until the claw 80 reaches the closed position 80B. A pawl 86 is mounted for rotation about a pin 88. Pawl 86 can move between a disengaged or unlatched position 86A and a latched or engaged configuration or position 86B. When claw 80 is in the closed position 80B, and pawl 86 is in the engaged position 86B, pawl 86 prevents rotation of claw 80 to the open position 80A, thereby preventing opening of door 1. Claw 80 may be biased by a spring or the like for rotation in a direction opposite the arrow R1 such that the claw 80 rotates to the open position 80A unless pawl 86 is in the engaged position 86B. Pawl 86 may be biased by a spring or the like in the direction of the arrow R2 such that pawl 86 rotates to the engaged position 86B as claw 80 rotates to the closed position 80B as striker 84 engages claw 80 as door 1 is closed. Latch 6 can be unlatched by rotating pawl 86 in a direction opposite the arrow R2 to thereby permit rotation of claw 80 from the closed position 80B to the open position 80A. A powered actuator such as an electric motor 92 may be operably connected to the pawl 86 to thereby rotate the pawl 86 to the disengaged or unlatched position 86A. Thus, in general, controller 8 can cause powered latch 6 to shift from a latched configuration or state to an unlatched configuration or state by causing powered actuator 92 to rotate pawl 86 from the latched or engaged position 86B to the unlatched configuration or position 86A. However, it will be understood that various types of powered latches may be utilized in the present invention, and the powered latch 6 need not include the claw 80 and powered pawl 86 as shown in FIG. 2. For example, powered actuator 92 could be operably interconnected with the claw 80 utilizing a mechanical device other than pawl 86 to thereby shift the powered latch 6 between latched and unlatched states. In general, vehicle door 1 can be pulled open if powered latch 6 is in an unlatched state, but the powered latch 6 retains the vehicle door 1 in a closed position when the powered latch 6 is in a latched state or configuration. As discussed in more detail below, an unlock switch 40 locks and unlocks powered latch 6.

Referring again to FIG. 1, the door 1 includes an interior door handle 12 that includes an elongated central portion 14 having a first or inner opposite side 22 (see also FIGS. 3 and 4) that faces interior surface 20 of door structure 2. The elongated central portion 14 of handle 12 also includes a second or outer opposite side 24 that generally faces away from the interior surface of the door 20. A space 26 is defined between the central portion 14 of handle 12 and the outer surface 20 of door structure 2. In use, a user can insert a portion of his/her hand into the space 26, and grasp the door handle 12 by wrapping his/her fingers around the central portion 14 of handle 12. As discussed in more detail below, a user can then push on an unlatch switch or button 28 with his or her thumb to provide a signal to controller 8 to unlatch the powered latch 6 if specified criteria are satisfied.

Referring again to FIGS. 3 and 4, door handle 12 may include an inner structure 30, an outer cover 32, and an intermediate space 34 between the inner structure 30 and outer cover 32. The inner structure 30 may comprise, for example, a rigid, tubular metal structure, and the outer cover 32 may comprise a flexible polymer, cloth, or other suitable material. The intermediate space 34 may be completely or partially filled with a solid polymer material, resilient foam, or other suitable material. Alternatively, the outer cover 34 may comprise a solid, one-piece molded component that fills space 34.

Handle 12 also includes first or inner capacitive sensors 36A, 36B, 36C that extend along inner side 22 of the central portion 14 of handle 12. The handle 12 also includes second or outer capacitive sensors/electrodes 38A, 38B, and 38C that extend along the second or outer side 24 of central portion 14 of handle 12. The capacitive sensors 36A-36C and 38A-38C may comprise elongated strips as shown in FIG. 1. The capacitive sensors 36A-36C (FIGS. 3 and 4) may be mounted on curved printed circuit boards 31, and the capacitive sensors 38A-38C may be mounted on curved printed circuit boards 33. The printed circuit boards 31 and 33 may be mounted to the inner structure 30. Circuit boards 31 and 33 may comprise rigid polymer material that is thermoformed or molded to provide a curved shape. Alternatively, the circuit boards 31 and 33 may comprise a flexible material that can be flexed as required to conform to the curvature of inner structure 30. End portions 31A and 33A (FIG. 1) of the printed circuit boards 31 and 33, respectively, may extend towards the end portion 16 of door handle 12. Electrical circuit components (not shown) may be mounted on the end portions 31A and/or 33A of the printed circuit boards 31 and 33, and one or more electrical lines 35 may be utilized to electrically connect the circuit boards 31 and 33 to controller 8. In the illustrated example, the capacitive sensors 36A-36C and 38A-38C generally extend between the lines designated “A” and “B” in FIG. 1. However, it will be understood that the capacitive sensors 36A-36C and 38A-38C may comprise various types of sensors as required for a particular application. For example, push buttons could also be mounted to the inner and outer sides 22 and 24 of handle 12 rather than the capacitive sensors just described. Optical sensors or the like could also be utilized to detect the presence of a hand on handle 12. Still further, a single capacitive sensor could be mounted on the inner side of handle 22, and a single capacitive sensor could be mounted on the outer side 24 of handle 12. Also, additional capacitive sensors/electrodes could be disposed on each side of the handle 12. For example, handle 12 could include six (6) capacitive sensors/electrodes on both the inner side 22 and outer side 24 to provide more sensitivity as to the firmness of the grip. Providing additional sensors or different sensors (e.g. push-button switches) provides additional data that can be utilized by controller 8 to determine if a user is casually grabbing the handle 12 with the intent to exit the vehicle or firmly grabbing the handle 12 to brace themselves for a potential impact or to hold firmly for a tight turn.

As discussed in more detail below, in use, a user grasps the central portion 14 of handle 12. If the user's hand is wrapped around the central portion 14 of handle 12, one or more of the first capacitive sensors 36A-36C and one or more of the second capacitive sensors 38A-38C will detect the presence of the user's hand. If the user presses or otherwise actuates the unlatch switch 28 within a predefined time interval (e.g. 3 seconds) of sensors 36A-36C and 38A-38C both detecting the presence of a user's hand, the controller 8 will cause the powered latch 6 to unlatch. As also discussed in more detail below, additional operating parameters or criteria may also be utilized by controller 8 to determine if powered latch 6 is to be unlatched.

With further reference to FIG. 5, the powered latch 6 may be operably connected to an exterior unlatch switch 42 of an exterior door handle (not shown). The powered latch 6 may also be connected to exterior control module 46 by lines 44. The exterior unlatch switch 42 and control module 46 provide for unlocking and unlatching of powered latch 6 from an exterior of a vehicle (provided access has been properly authorized) in a manner that is similar to known exterior latch release arrangements for vehicles equipped with powered latches.

As shown in FIG. 5, the unlatch switch 28 may comprise first and second normally open switches 28A and 28B that can be simultaneously closed by pushing switch member 28C. Switch 28 may optionally include an LED 52 that is illuminated if the vehicle headlights are on to assist a user in locating switch 28. Switch 28 may also include an LED (not shown) to indicate status of the switch 28 when closed. For example, the status LED may hold red for a few seconds if no hand was detected by electrodes 36A-36C and/or 38A-38C but show green if a hand was detected by the electrodes. It will be understood that the unlatch switch 28 could comprise other types of switches or it may comprise a sensor. The powered latch 6 is also operably connected to unlock switch 40. Referring again to FIG. 1, the unlock switch 40 may be positioned on interior surface 20 of door structure 2. The unlock switch 40 may be positioned adjacent interior handle 12 on door 1, or the unlock switch 40 may be positioned away from the door handle 12. The powered latch 6 and/or controller 8 may be configured (e.g. programmed) to provide a “locked” and an “unlocked” state. The controller 8 may be programmed to include locked and unlocked states such that predefined inputs to controller 8 are required to cause controller 8 to “unlock” to thereby permit controller 8 to unlatch powered latch 6. The vehicle may also include a lock switch 41 that is packaged adjacent to unlock switch 40. If the powered latch 6 and/or controller 8 is in a locked state, pushing the unlock switch 40 will cause the controller 8 to set its internal door lock status memory state to the unlocked state. If a valid request is made to release powered latch 6, it will be allowed by controller 8 since the controller 8 has a memory state record indicating that the door is unlocked. Conversely, if controller 8 has a memory state record that the door is in the unlocked state, pushing the locked switch 41 will cause the memory state of controller 8 for the door to change to the locked state. Alternatively, the unlock button 40 may comprise a toggle switch that causes the state of the controller 8 to change between locked and unlocked states each time the toggle switch is pressed or actuated.

Powered latch 6 and controller 8 may be operably connected to a vehicle data system 50 through a vehicle network 48. The vehicle data system 50 may include one or more modules and/or sensors that detect the speed of the vehicle. The vehicle data system 50 may also include sensors that detect lateral acceleration of the vehicle. For example, the vehicle data system 50 may include a Restraint Control Module (RCM) having lateral acceleration sensors and/or other sensors (e.g. pressure sensors in the vehicle door 1) that are utilized by the RCM to detect a crash event requiring deployment of the emergency constraints (e.g. airbags). As discussed in more detail below, data concerning the vehicle speed and/or data concerning lateral acceleration and/or other sensor data may be utilized by the powered latch 6 and/or controller 8 to control latching and unlatching of powered latch 6.

Powered latch 6 may include a backup or emergency power supply 62 comprising a battery, capacitors, or other electrical energy storage device. The backup power supply 62 may store enough electrical energy to actuate the powered latch 6 a limited number of times in the event of an emergency or loss of main vehicle power supply 49 or the local door power feed due to an open or shorted wire. Controller 8 may be configured to detect the loss of main vehicle power supply 49, and to utilize backup power supply 62 in the event of a loss of the local power feed or the main vehicle power supply 49.

Referring again to FIG. 5, the controller 8 is operably connected to the capacitive sensors 36A-36C and 38A-38C. As discussed above, controller 8 may be configured to determine if a user has grasped the interior handle 12 based on input from the capacitive sensors 36A-36C and 38A-38C. In general, the electrical signal from the capacitive sensors 36A-36C and 38A-38C may vary due to changes in temperature or other environmental factors. Controller 8 may be configured to recalculate a “baseline” reading for the capacitive sensors 36A-36C and 38A-38C, and compare the baseline value to a present value. In general, if a user grasps the door handle 12, this will cause one or more of the capacitive sensors 36A-36C and 38A-38C to provide a significantly different input voltage to the controller 8 relative to the baseline voltage, and the controller 8 may be configured to determine that a user's hand is present based on changes in inputs from the capacitive sensors. For example, controller 8 may be configured to determine that a user's hand is present if one or more of the first capacitive sensors 36A-36C have a significant change in input voltage at the same time that one or more of the second capacitive sensors 38A-38C also detect a significant change in input voltages. If controller 8 is configured in this manner, if any one of the sensors 38A-38C detects the presence of a hand at the same time as any one of the sensors 36A-36C also detects the presence of a hand, controller 8 will determine that a user has grasped the door handle 12. However, the specific criteria utilized by controller 8 to determine that a user has grasped handle 12 may vary as required for a specific application.

Controller 8 may also be configured to detect a potential crash event based, at least in part, on inputs from one or more of the capacitive sensors. For example, controller 8 may be configured such that simultaneous detection of a user hand by all of the capacitive sensors 36A-36C and 38A-38C indicates a potential crash event. For example, if the vehicle is experiencing a crash, or is about to crash, a user may grasp the door handle 12 tightly, thus causing all of the capacitive sensors 36A-36C and 38A-38C to detect the presence of a user's hand. Thus, simultaneous detection by all six of the capacitive sensors may be interpreted by controller 8 as indicating a potential crash event. If a potential crash event is detected in this manner, controller 8 may be configured to require that unlatch switch 28 be actuated twice within a predefined time interval (e.g. 3 seconds) in order to unlatch the powered latch 6. However, other combinations of detection by capacitive switches 36A-36C and 38A-38C may be construed by controller 8 as a “normal” unlatching situation such that a single actuation of unlatch switch 28 will cause powered latch 6 to unlatch provided that at least one of capacitive sensors 36A-36C detects a user's hand at the same time as at least one of the capacitive sensors 38A-38C also detects a user's hand.

Operation of the powered latch 6 is shown schematically in the flow chart of FIG. 6. Initially, at start 54 the powered latch 6 is in a latched configuration such that the vehicle door 1 cannot be opened. At step 56, controller 8 determines if capacitive sensors 36A-36C and 38A-38C have detected the presence of a user's hand. As discussed above, detection of a user's hand could involve various criteria as may be required for a particular application. According to one aspect of the present invention, a user's hand may be detected if at least one of the sensors 36A-36C detects a user's hand at the same time as at least one of the capacitive sensors 38A-38C detects the presence of a user's hand. As discussed above, this detection may be based on a change in input voltage from one or more of the capacitive sensors relative to a baseline voltage.

If a hand is not detected at step 58 the controller 8 determines if the unlock switch 40 was just actuated (e.g. was switch 40 actuated within the last 3 seconds?). If unlock switch 40 was not previously actuated within a predefined time interval, the controller returns to start 54. Referring again to step 56, if controller 8 does detect the presence of a user's hand at step 60, controller 8 determines if the vehicle has experienced a crash event, a loss of power, or a loss of data communication. The crash event may comprise a signal from the RCM module of vehicle data system 50 (FIG. 5). The loss of power may comprise a local loss of power or from main vehicle power supply 49 (FIG. 5). Referring again to FIG. 6, at step 60 a loss of data communication may be detected by controller 8 based on a loss of information from communication bus 48. As discussed above, the vehicle data system 50 may include a restraints control module and/or sensors that measure the vehicle speed. If communications from the vehicle data system 50 are lost, the controller 8 may not be able to determine the vehicle speed, a crash event, or the like. If a crash event, loss of power, or a loss of data communication is determined to have occurred at step 60, controller 8 may be configured to only unlatch powered latch 6 if unlatch switch 20 is pressed twice within a predefined time interval (e.g. 3 seconds) at step 64. If no crash event, loss of power, or loss of data communication is detected at step 60, controller 8 may be configured to unlatch powered latch 6 if unlatch switch 28 is pressed or actuated once as shown at step 66. Controller 8 may be configured to unlatch powered latch 6 only if unlatch switch 28 is actuated while the capacitive sensors detect a hand (step 56) and if the unlatch switch 20 is actuated simultaneously with detection of a hand at step 56. Alternatively, controller 8 may be configured to unlatch powered latch 6 if the capacitive sensors detect a hand (step 56) and if the unlatch switch 28 is actuated within a predefined time interval (e.g. 3 seconds) of the sensors detecting the presence of a hand (step 56). For example, if a user grasps the handle 12 and the sensors 36A-36C and 38A-38C detect the presence of the user's hand at a first time, and the user then releases the handle 12, but pushes or actuates the switch 28 within 3 seconds of the time at which sensors 36A-36C and 38A-38C detect the presence of a hand, the controller 8 could be configured to unlatch the powered latch 6.

Controller 8 may be configured to actuate powered latch 6 according to the logic set forth in tables 1, 1A and 2 as follows:

TABLE 1
NORMAL OPERATION MODE (FIRST CONFIGURATION)
Interior UNLATCH Button Operation per Door
(RCM Event Status OK for over 1 second from Ignition = OFF)
				Interior Rear Door (First Configuration)
MS-CAN		LOCK		Child Lock	Child Lock
Or VPWR	SPEED	STATUS	Interior Front Door	ON	OFF
OK	Speed < 3 kph	Locked &	Full Grasp & Push/	Full Grasp & Push/	Full Grasp & Push/
		Alarm	actuate switch 28 2 times	actuate switch 28 2	actuate switch 28 2
		Armed	within 3 seconds	times within 3 seconds	times within 3 seconds
		Locked	Full Grasp & Push/	No Unlatch	Unlock, Full Grasp &
			actuate switch 28		Push/actuate switch 28
		Unlocked	Full Grasp & Push/	No Unlatch	Full Grasp & Push/
			actuate switch 28		actuate switch 28
	3 kph < Speed <	ANY	Full Grasp & Push/	No Unlatch	Full Grasp & Push/
	8 kph		actuate switch 28		actuate switch 28
	Speed > 8 kph	ANY	Full Grasp & Push/actuate	No Unlatch	Full Grasp & Push/
			switch 28		actuate switch 28
Lost	Unknown	Unknown	Full Grasp & Push/	Full Grasp & Push/	Full Grasp & Push/
			actuate switch 28 2 times	actuate switch 28 2	actuate switch 28 2
			within 3 seconds	times within 3 seconds	times within 3 seconds

TABLE 1 A
NORMAL OPERATION MODE (SECOND CONFIGURATION)
Interior UNLATCH Button Operation per Door
(RCM Event Status OK for over 1 second from Ignition = OFF)
				Interior Rear Door (APA)
MS-CAN		LOCK		Child Lock	Child Lock
Or VPWR	SPEED	STATUS	Interior Front Door	ON	OFF
OK	Speed < 3 kph	Locked &	Full Grasp & Push/Actuate	Full Grasp & Push/Actuate	Full Grasp & Push/Actuate
		Alarm Armed	switch 28 2 times within 3	switch 28 2 times within 3	switch 28 2 times within 3
			seconds	seconds	seconds
		Locked	Full Grasp & Push/Actuate	No Unlatch	Full Grasp & Push/Actuate
			switch 28		switch 28
		Unlocked	Full Grasp & Push/Actuate	No Unlatch	Full Grasp & Push/Actuate
			switch 28		switch 28
	3 kph < Speed <	ANY	Full Grasp & Push/Actuate	No Unlatch	Full Grasp & Push/Actuate
	8 kph		switch 28		switch 28
	Speed > 8 kph	ANY	Full Grasp & Push/Actuate	No Unlatch	Full Grasp & Push/Actuate
			switch 28		switch 28
Lost	Unknown	Unknown	Full Grasp & Push/Actuate	Full Grasp & Push/Actuate	Full Grasp & Push/Actuate
			switch 28 2 times within	switch 28 2 × in 3 seconds	switch 28 2 × in 3 seconds
			3 seconds

TABLE 2
CRASH OR FUEL CUT OFF MODE
Interior UNLATCH Button Operation per Door
(RCM Crash/Fuel Event for less than 1 second from Ignition = OFF
					Interior Rear Door
MS-CAN		LOCK	Exterior Any		Child Lock
Or VPWR	SPEED	STATUS	Door	Interior Front Door	ON	Child Lock OFF
OK	Speed < 3 kph	Locked &	State Not Allowed (RCM Off when Security System Armed)
		Alarm Armed
		Locked	No Unlatch	Full Grasp & Push/Actuate	No Unlatch	Full Grasp & Push/Actuate
				switch 28 2 times within		switch 28 2 times within
				3 seconds		3 seconds
		Unlocked	No Unlatch	Full Grasp & Push/Actuate	No Unlatch	Full Grasp & Push/Actuate
				switch 28 2 times within		switch 28 2 times within
				3 seconds		3 seconds
	3 kph < Speed <	ANY	No Unlatch	Full Grasp & Push/Actuate	No Unlatch	Full Grasp & Push/Actuate
	8 kph			switch 28 2 times within		switch 28 2 times within
				3 seconds		3 seconds
	Speed > 8 kph	ANY	No Unlatch	Full Grasp & Push/Actuate	No Unlatch	Full Grasp & Push/Actuate
				switch 28 2 times within		switch 28 2 times within
				3 seconds		3 seconds
Lost	Unknown	Unknown	No Unlatch	Full Grasp & Push/Actuate	Full Grasp &	Full Grasp & Push/Actuate
				switch 28 2 times within	Push/Actuate switch	switch 28 2 times within
				3 seconds	28 2 times within	3 seconds
					3 seconds

As shown in tables 1 and 1A, the handle and latch system may have a first configuration or operating logic (table 1) or a second configuration or operating logic (table 1A). As can be seen in tables 1 and 1A, the interior rear handle and powered latch of the present invention may be configured differently depending on local laws/regulations. Operation of powered latch 6 may also be configured differently for use in front and rear interior door applications. In general, the same handle 12 (FIG. 1) may be utilized for both front and rear interior door applications in various geographic regions. The controller 8 may be configured to provide the operating logic set forth in tables 1, 1A and/or table 2 as required for a particular application.

In tables 1, 1A and 2, the designation “MS-CAN or VPWR” signifies the status of the vehicle communication bus 48 (FIG. 4) (MS-CAN) and the main vehicle power 49 (VPWR). Thus, controller 8 may be configured to require different inputs to unlatch powered latch 6 if the vehicle communication (MS-CAN) and/or main vehicle power (VPWR) is lost as shown in tables 1, 1A and 2.

In tables 1, 1A, and 2, the term “Full Grasp” generally corresponds to inputs from one or more of sensors 36A-36C and sensors 38A-38C that meet predefined criteria signifying a user has grasped handle 12. For example, the “Full Grasp” criteria could comprise simultaneous sensing by one or more sensors on opposite sides 22 and 24 of handle 12.

Also, as shown in tables 1, 1A and 2, controller 8 may be configured to require different inputs to unlatch the powered latch 6 depending on the vehicle speed. It will be understood that the listed speeds (e.g. 3 kph and 8 kph) are examples of speed criteria that could be utilized. However, the present invention is not limited to these specific speeds, and other speeds could be utilized according to other aspects of the present invention. Similarly, controller 8 may be configured to require actuation of switch 28 twice within 3 seconds under certain operating conditions in order to unlatch the powered latch 6. However, shorter or longer predefined time intervals (e.g. 2 seconds, 4 seconds, etc.) could be utilized according to other aspects of the present invention.

Furthermore, although the sensors 36A-36C and 38A-38C may be capacitive sensors, other sensors or switches positioned on the opposite sides 22 and 24 of door handle 12 (FIGS. 2 and 3) could also be utilized according to other aspects of the present invention. For example, the switches 36 and 38 could comprise mechanical switches that must be pushed by a user. Alternatively, the sensors 36 and 38 could comprise optical sensors, or the sensors 36 and 38 could comprise heart beat sensors.

Furthermore, the switches 36 and 38 (whatever type is used) could also function as lock and unlock switches in addition to providing information concerning the presence of a user's hand. For example, actuation of one or more of switches 38A-38C only (i.e. switches 36A-36B are not actuated) could be utilized by controller 8 as a lock signal, and actuation of only sensors 36A-36C (while none of the sensors 38A-38C are actuated) could be utilized by controller 8 as a unlock signal. However, simultaneous actuation of both sensors 36 and 38 could be utilized by controller 8 to signify the presence of a user's hand, and controller 8 may then unlatch powered latch 6 if unlatch switch 28 is actuated once within a predefined time interval and if controller 8 is in an unlocked state.

The handle and powered latch system of the present invention may also be configured to prevent inadvertent unlatching of powered latch 6 during emergency maneuvers. For example, with reference to table 1, if the vehicle is traveling at over 3 kph, and if the handle 12 is utilized in an interior front door configuration, controller 8 may be configured to require a full grasp (simultaneous actuation of at least one of sensors 36A-36C and sensors 38A-38C) and actuation of unlatch switch 28 twice within a predefined time interval (e.g. 3 seconds).

Also, the controller 8 may be configured to require that unlatch switch 28 is actuated twice within a predefined time interval (e.g. 3 seconds) if the RCM of the vehicle data system 50 detects a crash event as shown in table 2. Similarly, controller 8 may be configured to utilize lateral acceleration data from the vehicle data system 50 to determine that the vehicle is experiencing emergency maneuvers, and require that unlatch switch 28 be actuated twice within a predefined time interval during such emergency maneuvers.

The door handle 12 may also include a force detection feature as disclosed in co-pending U.S. patent application Ser. No. 14/282,224, filed on May 20, 2014, entitled “POWERED VEHICLE DOOR LATCH AND EXTERIOR HANDLE WITH SENSOR,” now U.S. Pat. No. 9,834,964 the entire contents of which are incorporated herein by reference. If door handle 12 includes a force sensor, controller 8 may be configured to utilize the force data due to a user's pushing or pulling on handle 12 to control powered latch 6. For example, controller 8 could be configured such that an outward force on handle 12 could be construed as indicating a user's intent to open the vehicle door 1. However, a user might not push on handle 12 until after switch 28 has been actuated, and controller 8 could be configured to construe an outward force after actuation of switch 28 as indicating that the user is pushing on the handle 12 to brace himself or herself, rather than indicating an intent to open the vehicle door 1. This force check by controller 8 could be done before or while de-bouncing the switch as discussed in U.S. patent application Ser. No. 14/282,224.

Controller 8 may also be configured to utilize combinations of inputs from the various sensors to further identify intent to open vehicle door 1. For example, if the vehicle data system 50 determines that the vehicle is experiencing a sudden maneuver in a hard right hand turn, controller 8 could be configured to require actuation of unlatch switch 28 twice within a predefined time interval to unlatch the doors on the driver's side. However, the passenger side doors could require outboard force on handle 12 and a single actuation of unlatch switch 28 during a hard right turn to unlatch powered latch 6. However, in the event the vehicle data system 50 determines that the vehicle is experiencing a sudden maneuver in a hard left turn, controller 8 may be configured to unlatch the driver's side doors only if outboard force on handle 12 is detected and a single actuation of switch 28 occurs, whereas the passenger side doors could require actuation of the switch 28 twice within a predefined time period during hard left turns. In general, if vehicle data system 50 does not measure significant lateral acceleration, the vehicle speed is less than a predefined threshold (e.g. 3 kph), and a user is applying an outboard force on door handle 12, controller 8 could be configured to allow a single actuation of switch 28 to unlatch the powered latch 6.

It is to be understood that variations and modifications can be made on the aforementioned structure without departing from the concepts of the present invention, and further it is to be understood that such concepts are intended to be covered by the following claims unless these claims by their language expressly state otherwise.

Claims

1. An electronic control system for controlling vehicle access, comprising: an electronic control system including a vehicle network operably interconnecting a programmable controller to a vehicle data system, the vehicle data system including at least one sensor configured to provide data concerning at least one vehicle operating parameter;a plurality of electronically powered latch mechanisms that are configured to be actuated to shift from a latched configuration to an unlatched configuration upon receipt of a signal from the electronic control system;first and second printed electronic circuit boards disposed on the interior handle, each having a plurality of electrically conductive elements;first and second sets of capacitive electrodes disposed on the curved outer surfaces of the first and second printed electronic circuit boards, respectively, wherein the electrically conductive elements are electrically coupled to the electrodes and the electronic control system such that actuation of the first and second electrodes causes corresponding first and second signals to be transmitted to the electronic control system; andan unlatch switch that is operably connected to the programmable controller;an unlock switch that is operably connected to the programmable controller:wherein the programmable controller has an internal door lock status memory, and the programmable controller is configured to set the door lock memory state to the unlocked state if the programmable controller receives a signal from the unlock switch, and wherein the programmable controller is configured to determine that a user has grasped the interior handle if any one of the first set of capacitive electrodes detect that a user's hand is present at the same time as any one of the second set of capacitive electrodes also detects the presence of a hand, and wherein the programmable controller is configured to unlatch the powered latch mechanism when a signal from the unlatch switch is received if the door lock memory state is set to an unlocked state and the programmable controller has determined that a user's hand is present.

2. The electronic control system of claim 1, wherein: the capacitive electrodes generate a first voltage if a user's hand is not present, and generate a second voltage if a user's hand is present, and wherein the programmable controller is configured to determine if a user's hand is present if a difference between the first and second voltages exceeds a predefined value.

3. The electronic control system of claim 2, wherein: the programmable controller is configured to recalculate a baseline first voltage to compensate for changes in the first voltage due to changes in temperature.

4. The electronic control system of claim 1, wherein: the programmable controller is configured to unlatch the powered latch mechanism only if the first and second sets of capacitive electrodes detect the presence of a user's hand within a predefined time interval of actuation of the unlatch switch.

5. The electronic control system of claim 4, wherein: the predefined time interval is three seconds.

6. The electronic control system of claim 1, wherein: the programmable controller is configured to unlatch the powered latch when a vehicle speed is above a predefined vehicle speed only if the first and second sets of capacitive sensors simultaneously detect the presence of a user's hand, and the unlatch switch is actuated twice within a predefined time interval.

7. The electronic control system of claim 1, wherein: the first and second sets of capacitive electrodes comprise elongated sensors extending along opposite sides of the interior handle;the programmable controller is configured to determine that a potential crash event has occurred if all of the capacitive electrodes simultaneously detect a user's hand, and wherein, if a potential crash event is detected, the programmable controller only unlatches the powered latch if the unlatch switch is actuated twice within a predefined time interval.

8. The electronic control system of claim 1, including: an acceleration sensor configured to measure lateral acceleration of a vehicle; and wherein:the programmable controller does not unlatch the powered latch if the acceleration sensor detects lateral acceleration above a predefined magnitude unless the unlatch switch is actuated twice within a predefined time.

9. The electronic control system of claim 1, wherein: the interior handle includes a force sensor that detects a force applied to the handle by a user;the programmable controller does not unlatch the powered latch unless the first and second sensors detect the presence of a user's hand, the unlatch switch is actuated, and the force sensor detects a force exceeding a predefined magnitude.

10. The electronic control system of claim 1, wherein: the programmable controller shifts from the unlocked state to the locked state if the second set of capacitive electrodes detect the presence of a user's hand while the first set of capacitive electrodes simultaneously do not detect the presence of a user's hand.

11. The electronic control system of claim 1, wherein: the first and second electronic circuit boards include curved outer surfaces facing in opposite directions.

12. A vehicle door, comprising; a door structure having a manually actuated switch on an interior side thereof;an interior door handle having capacitive sensors disposed on opposite sides thereof;;a powered latch; anda controller configured to unlatch the powered latch if the capacitive sensors detect a user's hand on the opposite sides of the handle and the switch is actuated with a predefined time interval of the sensors detecting a user's hand.

13. The vehicle door of claim 12, wherein: the interior door handle includes first and second opposite ends that are secured to the door structure and a central portion that is spaced apart from the door structure to define a gap that, in use, receives a portion of a user's hand.

14. The vehicle door of claim 12, wherein: the manually actuated switch comprises a pushbutton switch that faces away from the door structure.

15. A method of controlling a powered door latch of a vehicle, the method comprising; providing a door structure having an interior handle and a powered latch configured to selectively retain the door in a closed position;providing capacitive sensors on opposite sides of the interior handle;unlatching the powered latch only if the capacitive sensors on opposite sides of the handle detect a user's hand.

16. The method of claim 15, including: providing a switch; and wherein:the powered latch is unlatched only if the switch is actuated within a predefined time interval of detection of a user's hand by the sensors.