RU2711417C2 - Transmission compensation for key fob - Google Patents

Abstract

FIELD: physics.SUBSTANCE: disclosed is a method of adjusting the output power of a key ring. First output signal is transmitted at first installed power. First feedback signal is received by means of a feedback mechanism in a key fob, which indicates the first level of output power of the first output signal. First level of output power is compared to the threshold level. Second output signal is transmitted at second installed power higher than first installed power if first level of output power is below threshold level. Key fobs are also disclosed.EFFECT: enabling higher reliability.20 cl, 5 dwg

Description

CROSS REFERENCE TO RELATED APPLICATIONS

[0001] This application is related to US patent application No. _________ filed March 30, 2015 (case number 83512203 (65080-1539)), called “KEY FOB TRANSMISSION COMPENSATION” and patent application No. _________ filed March 30, 2015 (case number 83512215 (65080-1566)), under the name “FOB CASE FOR REDUCED TRANSMISSION INTERFERENCE”, the full contents of which are hereby incorporated by reference in their entirety.

BACKGROUND

[0001] The remote keyless entry system (RKE system) includes a remote device, sometimes called a key fob or key fob, used by a vehicle operator and in communication with a base unit integrated in the vehicle. The range of the RKE system, i.e. the distance between the key fob controlled by the vehicle operator and the base unit is a characteristic of the perceived quality of the system. The range of the system varies according to the output of the transmitter's radio frequency (RF) power, which is limited by federal regulations.

BRIEF DESCRIPTION OF THE DRAWINGS

[0002] FIG. 1 is a diagram of an example keyless entry remote access system.

[0003] FIG. 2 is a block diagram of an example remote keyless entry system of FIG. 1.

[0004] FIG. 3 is a perspective view of the key fob in FIG. 1, including an array of capacitive sensor leads.

[0005] FIG. 4 is a diagram of an example process for adjusting a set output power based on detection of a hand operating a key fob in FIG. 1.

[0006] FIG. 5 is a diagram of an exemplary process for using the internal feedback mechanism to adjust the installed output power of the transmitter in FIG. 1.

DETAILED DESCRIPTION OF THE INVENTION

INTRODUCTION

[0007] The adjustable power level of the key fob is measured in “free space” without touching a person’s hand or near the key fob. A person’s hand in the vicinity of a transmitter / receiver antenna in the key fob may interfere with transmission and reduce RF output power. Human interaction with the key fob can change the antenna pattern so that there is a lower gain in the direction of the vehicle. Additionally, when the key fob battery reaches the end of its life (most of its charge has been used up), the output power of the key fob may decrease. Reduced power output reduces the range of the RKE system, which potentially leads to operator dissatisfaction.

[0008] FIG. 1 illustrates an exemplary Remote Keyless Entry (RKE) system 10 for a vehicle 12, including one or more output power adjustment mechanisms to compensate for interference from an object, such as an operator. The RKE system 10 provides remote control from the key fob 14 for various applications in the vehicle 12, such as door locks, tailgate closure, interior and exterior lighting, engine starting, climate control, etc. Vehicle 12 is a generally ground vehicle having two or more wheels, for example, a passenger car, light truck, motorcycle, etc. Vehicle 12 includes a base station 16 for receiving messages from the key fob 14 and possibly transmitting messages to the key fob 14.

[0009] The key fob 14 transmits messages to the base station 16 and can also receive messages from the base station 16. The key fob 14 includes a housing 18 and an interface 20. The interface 20 receives input from and provides output to the operator.

[0010] To determine the installed output power, the keyfob 14 may include one or more sensors for detecting the presence of an operator near or holding the keyfob 14. The keyfob 14 may further include one or more feedback mechanisms for detecting the actual output power level and comparing the detected output power level with stored threshold value. Based on the information from the sensors and / or feedback mechanisms, the key fob 14 can adjust the level of output power. Adjusting the output level of the keyfob 14 to compensate for interference allows, for example, the keyfob 14 to be in communication with the vehicle 12 at a longer range and may increase operator satisfaction with the RKE system 10. In addition to adjusting the output power level of the keyfob 14, adjusting other communication parameters, such as sleep mode (delay time between sending the transmission and receiving the response), data rate, preamble time, etc., can be performed.

SYSTEM ELEMENTS

[0011] As shown in FIG. 2, the vehicle 12 includes a base unit 16 and further includes control units 38 and an interface 40.

[0012] The base station 16 includes a controller 30 including a processor 31 for executing programs stored in the memory 33. The base station 16 further includes a receiver 32 and a transmitter 34, both in communication with the controller 30. The base station 16 further includes one or more transceiver antennas 36 for receiving output signals from the key fob 14 and transmitting the output signals to the receiver 32. If the base station 16 includes a transmitter 34, the transmitter 34 may also use one or more transceiver a antenna 36 for transmitting messages to the keyfob 14.

[0013] The base station 16 is in direct or indirect communication with one or more control units 38. The control units 38 can control various functions of the vehicle 12, such as locking the doors, closing the boot, interior / exterior lighting, climate control, starting the engine, etc. Each control unit 38 may have a processor for receiving instructions from the base station and controlling the drive. For example, a door lock control unit may include a processor and a motor (or solenoid) for opening / closing a door lock. Additionally, the control units 38 may be able to send messages to the controller 30 of the base station 16. For example, the door lock control unit 38 may send a signal to the controller 30 of the base station 16 that the door is locked.

[0014] Communication between the controller 30 and the control units 38 may be via a network bus, for example, a CAN bus (controller network), or other wired or wireless mechanisms. The controller 30 may include one or more processors. In the event that the controller 30 includes more than one processor, communication between the processors may also be via a network bus. In addition, the controller 30 may be configured to communicate with other devices via various wired and / or network technologies, for example, cellular, Bluetooth® universal serial bus (USB), wired and / or wireless packet networks, etc.

[0015] Additionally, the vehicle 12 generally includes an interface 40. In general, the interface 40 is equipped to receive input for and / or provide output from the controller 30. For example, the vehicle 12 may include one or more displays configured to provide a graphical operator interface (GUI) or the like, an interactive voice response system (IVR), audio output devices, mechanisms for providing tactile output, etc., providing communication between the vehicle 12 operator. Additionally, an operator device, for example, a portable computing device, such as a tablet computer, smartphone or the like. can be used to provide some or all of the interfaces 40 to the controller 30. For example, an operator device can be connected to the controller 30 using the technologies discussed above, for example, USB, Bluetooth®, etc., and can be used to receive input for and / or providing output from the controller 30.

[0016] The controller 30 may be implemented directly or indirectly, i.e. by another computing device in the vehicle 12, with the possibility of communication with the network 21. The network 21 is one or more mechanisms by which the vehicle 12 can be in communication with remote computing devices, and can be one or more different wired or wireless communication mechanisms, including any desired combination of wired (for example, cable and fiber) and / or wireless (for example, cellular, wireless, satellite ide, microwave frequency and radio frequency) of communication mechanisms and any desired network topology (or topology when using multiple communication mechanisms). Exemplary communications networks include wireless communications networks (eg, using Bluetooth, IEEE 802.11, etc.), local area networks (LAN) and / or wide area networks (WANs), including the Internet, providing data services.

[0017] As shown in FIG. 2, the key fob 14 includes a controller 50 including a processor 51 and a memory 53. The processor 51 is configured to execute programs stored in the memory 53 and control various functions of the key fob 14, for example, transmitting messages to a vehicle 12, receiving messages from vehicle 12, output power calibration, etc. As described below, the processor 51 may also be programmed to perform one or more processes to adjust the output power level during operation.

[0018] The keyfob 14 further includes a transmitter 52 and at least one transceiver antenna 56. The transmitter 52 is communicatively coupled to the controller 50 and configured to transmit RF messages via the transceiver antenna 56 to the vehicle 12. The transmitter 52 includes a mechanism calibration to set the maximum installed output power; and a setup mechanism to adjust the output power level during operation.

[0019] To support bidirectional communication, the keyfob 14 may include a receiver 54 communicatively coupled to the controller 50. The receiver 54 may be configured to receive RF communications from, for example, vehicle 12 via a transceiver antenna 56.

[0020] At least one transceiver antenna 56 may include, for example, a first and second transceiver antenna 56. Under certain operating conditions, the processor 51 may be programmed to use both the first and second transceiver 56 in a balanced configuration for transmission or reception messages. That is, in transmission mode, each of the first and second transceiver antennas 56 can transmit, for example, at a substantially equal power level. Under other operating conditions, the processor 51 may be programmed to select one of the two transceiver antennas 56 to transmit or receive and disconnect the other antenna 56 during transmission or reception. In other operating conditions, the processor 51 may adjust the tuning between the first and second transceiver antennas. As described below, the processor may take into account operating conditions, such as the position of the hand holding the keyfob 14, to determine the antennas used, the number of antennas, and the settings between the transmit-receive antennas 56 for transmission or reception.

[0021] As discussed above, the key fob 14 includes an interface 20 for receiving input from and providing output to an operator, such as a driver of a vehicle 12. The interface 20 includes one or more input devices and may include a display. Input devices can be buttons, a touch screen display, gesture detection device, etc. to receive input from the operator. The display may include an LCD display, an LED display, audible alarms, speakers, tactile feedback, etc. to provide information to the operator.

[0022] The key fob 14 may include one or more sensors 60 that may be communicatively coupled to the controller 50. The sensors 60 may be used to detect the presence of an object, such as a person’s hand, near or in direct contact with the key fob 14. Sensors 60 may further detect whether an object is located near the transceiver antenna 56. For example, sensors 60 may include one or more capacitive sensors, resistive sensors, electromagnetic sensors, optical sensors, etc. In addition to detecting the presence of the object and the proximity of the object to the transceiver antenna 56, the sensors 60 can detect, for example, the size, position, orientation, conductivity, or other characteristics of the object. The sensors 60 may be located in a matrix, for example, a 3x3 matrix of capacitive sensors distributed over the surface of the key fob 14 in order to receive additional information regarding the characteristics of the object near the key fob 14.

[0023] As an addition or alternative, the sensors 60 may include accelerometers, gyroscopes, magnetic field sensors, etc. used to detect the movement or orientation of the key fob 14. The processor 51 may be programmed, for example, based on the movement of the key fob 14 which is detected by one or more sensors 60, with the possibility of determining whether the keychain is held by a person 14, whether it is in a person’s pocket, is stationary, etc.

[0024] The keyfob 14 may further include a feedback mechanism 62 for sending a feedback signal indicative of the output power level to the controller 50. The feedback mechanism may include a radio frequency (RF) detection element 63. The RF detection element 63 may be, for example, tracks on a printed circuit board that are remote from the transceiver antenna 56. As an addition or alternative, when there is more than one transceiver antenna 56, the controller 50 can control the keyfob 14 so that when one transceiver antenna 56 is used to transmit the message, another transceiver antenna 56 is used as the RF detection element 63.

[0025] The battery 64 supplies power to the key fob 14. The key fob 14 may include a charge state unit (SOC) 66 for monitoring the state of charge of the battery 64. The SOC 66 may track the output voltage, output current, output resistance, etc. battery 64. Based on these monitored values, the computing device in SOC 66, the processor 51, or other computing device can determine the estimated state of charge of the battery 64. Based on the determination of the low battery state, the processor 51 can adjust the output power level and / or adjust other communication parameters. In addition or alternative, the processor 51 may report charge state information to the vehicle 12.

CALIBRATION OF THE MAXIMUM OUTPUT POWER LEVEL

[0026] To reduce or possibly eliminate interference with other communication systems, and when applicable to comply with the standards, the key fob 14 can be calibrated to transmit at an output power level less than or equal to the maximum power level. The test can be carried out on an exemplary sample of the keyfob 14 according to a particular type of design or model. The key fob 14 can transmit a message at a known installed output power under known conditions. To prevent interference due to the presence of a human hand or other conductive objects, the key fob 14 can be activated (for example, the transmission button can be pressed) by means of an object made of non-conductive material. The output power level can be measured by a measuring unit at a known distance, for example, one meter, three meters, etc. from the keyfob 14. Based on the measured output power level, the component value in the transmitter 52 of the keyfob 14 can be adjusted, or the correction of the set power level can be determined. Component adjustment or adjustment of the set power level can be included in the manufacture of key fobs 14 with one type of design or model. For example, the initial or first set power level corresponding to the maximum power level under calibration conditions may be stored in the memory 53 of the controller 50.

COMPENSATION FOR ADJUSTING INTERFERENCE ON THE BASIS OF OBJECT DETECTION

[0027] An object, such as a human hand, in the vicinity of the transmitter-transmitter antenna 56 of the keyfob 14 can cause a decrease in the output power level of the keyfob 14 and cause transmission interference. As noted above, Human interaction with the key fob can change the antenna pattern so that there is a lower gain in the direction of the vehicle. This can cause a decrease in the range of the RKE system, and lead to a decrease in operator satisfaction. To compensate for the decrease in the output power level, the keyfob 14 can adjust the installed output power based on the detection of an object near the transceiver antenna 56. Proximity to the transceiver antenna 56 can be defined, for example, as direct contact with at least one sensor 60 on the keyfob body 18. as another example, proximity to the transceiver antenna 56 can be defined as touching the keyfob body 14 within three centimeters of the transceiver antenna 56 on a particular side of the br Christmas tree 14 (for example, the side usually facing the vehicle 12 when the keyfob 14 is operating). As another example, proximity to the transceiver antenna 56 can be defined as being within the detectable range of the gesture recognition system 60 included in the keyfob 14, for example, five centimeters.

[0028] The sensors 60 can be used to detect the presence of an object near the transceiver antenna 56. The sensors 60, when detecting an object, can provide data to the controller 50. For example, one or more capacitive sensors 60 can be included in the keyfob housing 18. One or more capacitive sensors 60 may be placed with the possibility of detecting a hand or other object touching the keyfob 14 three centimeters or less from the transceiver antenna 56.

[0029] As another example, the sensors 60 may include gesture or proximity sensors, which are known, for example, optical, capacitive, magnetic sensors 60. The sensors 60 can detect the presence of a hand or other object in a space close to the transceiver antenna 56, located or not, the object is in direct contact with the key fob 14.

[0030] Based on the detection of the object, the sensors 60 may send a message to the processor 51 indicating the presence of the object near the transceiver antenna 56. Based on the message, the processor 51 can adjust the set output power by a predetermined adjustment factor. The predetermined adjustment factor may be a value determined to compensate for the level of output power for interference caused by the object without exceeding the maximum power level. The predetermined adjustment factor can be determined empirically. For example, tests can be performed in a controlled environment to determine the minimum power loss that occurs when an object is near the transceiver antenna 56. A predetermined adjustment factor can be determined to compensate for the minimum power loss. The margin of error can be included in the determination of a given adjustment coefficient to ensure changes in the performance of individual blocks and changes due to differences between objects.

[0031] In addition to detecting the presence of an object near the transceiver antenna 56, the sensors 60 can detect and communicate additional characteristics regarding the object to the processor 51. For example, as shown in FIG. 3, the keyfob 14 may include a capacitive sensor array 60 including a plurality of capacitive sensors disposed at different positions on the keyfob 14. Based on the signals from the capacitive sensor matrix 60, the processor 51 may determine that the object is, for example, near the right side key fob 14. Based on the definition, the processor 51 may, for example, use the first transceiver antenna 56 on the left side of the key fob 14 to transmit a message and disconnect the second transceiver antenna 56 on the right side of the key fob 14, or adjust configuration between th e first antenna and a second transceiver 56.

[0032] As another example, based on the input from the sensors 60, the controller 50 can estimate the level of interference. The processor 51 may receive input, for example, that an object covers a small area or a large area surrounding a transceiver antenna 56, and select one or more predetermined adjustment factors based on an estimated interference level.

[0033] As noted above, in addition to adjusting the output power level of the key fob 14, adjusting other communication parameters such as sleep mode, data rate, preamble time, etc., can be performed.

[0034] Sensors 60 can be used to prevent accidental activation of key fob 14. For example, processor 51 can be programmed to receive input from interface 20 only when the controller determines that an object (such as a hand) is based on input from sensors 60 person) is in contact with the key fob 14.

[0035] As an addition or alternative, some sensors 60 can only be activated (turned on) only when the processor 51 has received input from the interface 20. Thus, the power consumption of the sensors 60 can be reduced.

FEEDBACK ADJUSTMENT

[0036] The feedback mechanism 62 may be used to monitor and adjust the output power of the keyfob 14. As described above, the RF detection element 63 or other antenna included in the keyfob 14 may receive an output signal from the transceiver antenna 56. RF detection element 63 or another antenna may transmit the output to feedback mechanism 62. Based on the received output signal, the feedback mechanism may provide a feedback signal to the processor 51. By monitoring the feedback signal, the processor 51 can recognize when the output signal approaches the maximum power level.

[0037] In an exemplary process, the processor 51 initially determines the feedback signal level corresponding to the maximum power level. During calibration, as described above, the example keyfob 14 is adjusted to operate at maximum power level. During operation at the maximum power level, the controller 50 may receive and store in memory 53 the feedback signal level corresponding to the maximum power level. Based on at least partially this level, the stored threshold value can be determined. For example, the stored threshold value can be defined as the level of the feedback signal during operation of the keyfob 14 at the maximum power level minus the safety factor, which is described below.

[0038] During transmission by the keyfob 14 in the standard mode of operation, the feedback signal can be monitored by the processor 51. If the feedback signal is lower than the stored threshold value, the processor 51 can increase the set output power.

[0039] The safety factor can be determined to account for changes in the manufacturing process of the keyfob 14. The safety factor can be further determined to account for the expected change in the output power level based on the smallest adjustment available for the installed power. In other words, the stored threshold value can be selected so that the adjustment of the installed power will not lead to exceeding the maximum power level. The stored threshold value may be stored in the memory 53 of other key fobs 14 of the same design during the manufacturing process.

[0040] As an example, the controller 50 may gradually increase the installed output power. The increase gain may be a constant value based on the characteristics of the transmitter 52 of the keyfob 14. For example, the installed output power may have a constant number of values, and the controller 50 may select the next higher value. Alternatively, the increase gain can be calculated based on the level of the feedback signal. The processor 51 may calculate an adjustment value based on a feedback signal indicating how much the set output power can be increased to approach without exceeding the maximum output power. The processor 51 may further increase the set output power according to the adjustment value. After increasing the installed output power, the processor 51 may continue to monitor the feedback signal to determine if additional adjustment is required.

[0041] In addition to adjusting the set output power based on the feedback signal, the processor 51 may be programmed to adjust the settings of the transceiver antennas 56. For example, the processor 51 may redistribute the tuning between the first and second transceiver antennas 56 so that, for example, the first transceiver the antenna 56 transmits at a higher power level than the second transceiver antenna 56, and determine whether the feedback signal level increases based on the redistribution.

[0042] In the event that the keyfob 14 is malfunctioning so that the feedback signal exceeds the stored threshold value, the processor 51 can also be programmed to reduce the set output power, and / or, if the condition persists, turn off the transmitter 52 of the keyfob 14. Adjustments Other communication parameters can also be performed.

[0043] The processor 51 may further be programmed to use data from the sensors 60, as well as feedback from the feedback mechanism 62 to adjust the installed output power of the keyfob 14. As an example, the processor 51 may be programmed, as described above, with the possibility adjusting the installed output power by means of a predetermined value based on data received from sensors 60. After adjustment, the controller 50 may determine, based on the feedback signal from the mechanism 62, If there is a need for additional adjustment.

REPORT OF CHARACTERISTICS OF THE BATTERY

[0044] The key fob 14 may include a charge state unit (SOC) 66 for evaluating the remaining charge in the battery 64. The SOC 66 may measure the output voltage, output current, output resistance, etc. battery during operation and based on these measurements to determine the characteristics of the battery 64, for example, the estimated remaining charge. Based on the specific characteristics of the battery 64, the keyfob 14 may adjust the performance of the keyfob 14. For example, if it is determined that the output voltage of the battery 64 drops due to a low charge state, the processor 51 may adjust the installed power of the transmitter 52 or adjust other communication parameters. In addition or alternative, the key fob 14 may report the characteristics of the base station 16 of the vehicle 12.

[0045] Similarly, the base station 16 may, based on the characteristics of the battery 64, adjust the operation of the base station 16. For example, if the base station 16 receives a message that the estimated remaining charge of the battery 64 is below the first threshold charge level, the base station 16 may increase the sensitivity of the receiver 32 base station 16. The first threshold level of charge can be empirically defined as the level of charge at which, for example, the output power of the transmission decreases by approximately 20% in the remote control 14 designs.

[0046] As another example, when the base station 16 receives a message that the estimated remaining charge in the battery 64 is below the second threshold charge level, the base station 16 may, for example, via the interface 40, display a message that the battery 64 is near the end of its life , or, if applicable, should be recharged. The second threshold charge level can be empirically defined as the charge level at which, for example, the battery 64 can support certain operating conditions for the 100 additional optional transmissions of the keyfob 14. The base station 16 can additionally, for example, provide information related to the state of the battery 64 to the operator via network 21, for example, via email.

EXAMPLE PROCESSES

[0047] FIG. 4 is a diagram of an example process 100 for compensating for interference to a keyfob 14 based on the detection of an object near the transceiver antenna 56 of the keyfob 14, generally performed according to instructions by a processor 51.

[0048] The process 100 begins at block 105, in which the keyfob 14 detects operator input from the interface 20. For example, the interface 20 may include multiple buttons. The operator of the vehicle 12 may press one of the buttons, providing input to the processor 51. The processor 51 determines based on the input that the operator wishes to transmit a message to the vehicle 12. The process 100 continues to block 110.

[0049] At block 110, the processor 51 receives input from one or more sensors 60. As described above, the sensors 60 may provide detection input indicating that the object is in direct contact with the keyfob 14 and may indicate a position or positions on keychain 14, which are in direct contact with the object. The sensors 60 may further indicate whether the object is located near the transmitter-transmitter antenna 56 of the keyfob 14. Additionally, the sensors 60 may provide other information, such as the orientation of the keyfob 14, the movement of the keyfob 14, etc. The processor 51 may receive and store input from sensors 60. The process 100 continues at block 115.

[0050] At block 115, the processor 51 may determine the characteristics of the object. For example, based on the position or positions of the key fob 14 in direct contact with the object, the controller 50 may determine that the key fob 14 is held by hand on the right side or the left side. Based on input indicating the orientation or movement of the keyfob 14, the processor 51 may determine, for example, that the keyfob 14 is held in a horizontal position. The processor 51 may determine other characteristics of the object, for example, the extent to which the object covers the key fob 14, the conductivity of the object, etc. The process 100 continues at block 120.

[0051] At block 120, the processor 51 may determine the adjustment of the set power level. As described above, the installed output power can be controlled by a predetermined adjustment factor. The predetermined adjustment coefficient may be a constant value or may be selected from several predetermined adjustment factors based on certain characteristics of the object. Process 100 continues at block 125.

[0052] In block 125, the processor 51 adjusts the installed output power of the transmitter 52 of the keyfob 14 according to a predetermined adjustment coefficient determined in block 120. As described above, the processor 51 can send instructions to the transmitter 52, and based on the instructions, the transmitter 52 can adjust the installed output power with taking into account the given adjustment coefficient. In addition or alternative, the processor 51 may adjust other communication parameters. The process 100 continues at block 130.

[0053] At block 130, the processor 51 instructs the transmitter 52 of the keyfob 14 to transmit a message to the vehicle 12. The transmitter 52 transmits a message at a set output power set at block 125. The process 100 may terminate when the transmission ends.

[0054] FIG. 5 is a diagram of an exemplary process 200 for compensating for interference for a keyfob 14 based on feedback from a feedback mechanism 62, generally executed according to instructions by a processor 51.

[0055] The process 200 begins at block 205, in which the keyfob 14 detects operator input from the interface 20. As described with respect to the process 100, the interface 20 may include a plurality of buttons. The operator of the vehicle 12 may press one of the buttons, providing input to the controller 50. The processor 51 determines based on the input that the operator wishes to send a message to the vehicle 12. The process 200 continues at block 210.

[0056] In block 210, the processor 51 sets and / or increases the installed power level of the transmitter 52 of the keyfob 14. For initial transmission, after detecting operator input, the processor 51 may set the installed power level to the original installed power. The initial power level may be, for example, the initial installed power determined by calibrating the keyfob 14, as described above. For subsequent transmission, the installed power can be gradually increased. The magnitude of the increase may be a constant value or a value determined based on the value of the feedback signal, as described above. In addition or alternative, the processor 51 may perform adjustments to other communication parameters. The process 200 continues at block 215.

[0057] In block 215, the keyfob 14 transmits a message to the vehicle 12. The processor 51 sends an instruction to the transmitter 52, which transmits a message at the installed power set in block 210. The process 200 continues in block 220.

[0058] In block 220, the processor 51 determines whether the value of the feedback signal is less than the stored threshold value. The feedback mechanism 62 provides a feedback signal to the controller indicating the output power level of the output signal transmitted from the transmitter 52. The processor 51 compares the feedback signal with the stored threshold value. If processor 51 determines that the feedback signal is below a stored threshold, process 200 continues at block 210 and begins another transmission at a higher installed power, as described above. If the processor 51 determines that the feedback signal is greater than or equal to a predetermined threshold value, the process 200 ends.

[0059] The expression “exemplary” is used herein to mean an example, for example, the mention of “exemplary fixture” should be understood simply as a reference to an example of fixture.

[0060] In the drawings, like reference numerals indicate like elements. In addition, some or all of these items are subject to change. Accordingly, it should be understood that the above description is intended to illustrate and not limit. Many of the options for implementation and application, other than the above examples, will be clear to a person skilled in the art when reading the above description. The scope of protection of an invention should not be determined by referring to the above description, but by referring to the attached claims along with the full scope of protection of equivalents to which such claims apply. It is expected and expected that improvements will be made in the art discussed here in the future, and that the disclosed systems and methods will be included in such future embodiments. In summary, it should be understood that the invention may be modified and modified, and limited only by the following claims.

Claims (47)

1. A method of adjusting the output power of the key fob, comprising the steps of: transmitting a first output signal at a first installed power; receiving, by the feedback mechanism in the key fob, a first feedback signal indicating a first output power level of the first output signal; comparing the first output power level with a threshold level; and transmitting a second output signal at a second installed power greater than the first installed power if the first output power level is below a threshold level. 2. The method according to p. 1, further comprising stages in which: receiving, by a feedback mechanism, a second feedback signal indicating a second output power level of the second output signal; comparing the second output power level with a threshold level; transmit a third output signal at a third installed power greater than the second installed power if the second output power level is below a threshold level. 3. The method of claim 1, further comprising the step of determining a threshold level from the calibration data. 4. The method according to claim 1, further comprising the step of determining the first installed power from the calibration data. 5. The method of claim 1, wherein the feedback mechanism includes an RF detection element. 6. The method of claim 1, wherein the keyfob includes a plurality of transceiver antennas, the plurality of transceiver antennas including a first transceiver antenna and a second transceiver antenna, the method further comprising the steps of: receive a detection signal from the sensor; determine the position of the object near the transmitter based on the detection signal; selecting one of the first transceiver antenna and the second transceiver antenna to transmit the first output signal based on the determination of the position of the hand; and choose another from the first transceiver antenna and the second transceiver antenna for feedback transmission of the first output signal to the feedback mechanism. 7. The method of claim 1, further comprising the step of: transmitting a fourth output signal at a fourth installed power less than the first installed power if the first output level is above a threshold level. 8. The method according to claim 1, in which the first installed power is increased by a first value to a second installed power, the first value being based on empirical data. 9. The method according to claim 1, wherein comparing the first output power level with a threshold value includes the steps of calculating the difference between the first feedback signal and the threshold level and determining the first value based on at least partially calculated difference. 10. A keychain containing: a memory device; transmitter; a feedback mechanism programmed to provide a first feedback signal; and a processor programmed to transmit a first output signal at a first installed power, receive a first feedback signal indicating a first output power level of a first output signal, compare a first output power level with a threshold level, and transmit a second output signal at a second installed power if the power level the first feedback signal is below a threshold level, the second installed power being greater than the first installed power. 11. The key fob of claim 10, wherein the processor is further programmed to receive a second feedback signal indicating a second power level of the second output signal by a feedback mechanism, comparing the second output level with a threshold level and transmitting a third signal at a third installed power, greater than the second installed power if the second output power level is below a threshold level. 12. The key fob according to claim 10, in which the stored threshold level is determined from the calibration data. 13. The key fob of claim 10, wherein the first installed power is determined from the calibration data. 14. The key fob of claim 10, wherein the feedback mechanism includes an RF detection element. 15. The key fob according to claim 14, wherein the feedback antenna is a conductor track remote from the transceiver antenna included in the key fob. 16. The keychain of claim 10, further comprising: a plurality of transceiver antennas, the plurality of transceiver antennas including a first transceiver antenna and a second transceiver antenna; and at least one sensor; moreover, the processor is additionally programmed with the ability to: receiving a detection signal from at least one sensor, determining the position of the object near the transmitter based on the detection signal, selecting one of the first transceiver antenna and the second transceiver antenna for transmitting the first output signal based on the determined position of the object; and selecting another of the first transceiver antenna and the second transceiver antenna for feedback feedback of the first output signal to the feedback mechanism. 17. The key fob of claim 10, wherein the processor is further programmed to transmit a fourth output signal at a fourth installed power less than the first installed power if the first output power level is greater than a threshold level. 18. The key fob of claim 10, wherein the first installed power is increased by a first amount to a second installed power, the first value being based on empirical data. 19. The key fob of claim 10, wherein comparing the first output power level with a threshold value includes calculating a difference between the first feedback signal and the threshold level and determining a first value based on the at least partially calculated difference. 20. A keychain containing: a memory device; transmitter; a plurality of transceiver antennas, including a first transceiver antenna and a second transceiver antenna; a feedback mechanism programmed to provide a first feedback signal; and a processor programmed to transmit the first output signal at the first installed power, receive a first feedback signal indicating the first output power level of the first output signal, compare the first output power level with a threshold level, and adjust settings between the first transceiver antenna and the second transceiver antenna, if the power level of the first feedback signal is below a threshold level.

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