Fast scan trainable transmitter

Description

BACKGROUND OF THE INVENTION
The present invention relates to a remote control RF transmitter and particularly to a trainable transceiver for a vehicle that transmits a control signal to a remotely controlled device such as a garage door opener.
Electrically operated garage door opening mechanisms are an increasingly popular home convenience. Such garage door opening mechanisms typically employ a battery-powered portable RF transmitter for transmitting a modulated and encoded RF signal to a separate receiver located within the homeowner's garage. Each garage door receiver is tuned to the frequency of its associated remote transmitter and demodulates a predetermined code programmed into both the remote transmitter and the receiver for operating the garage door. Conventional remote transmitters have consisted of a portable housing which typically is clipped to a vehicle's visor or otherwise loosely stored in the vehicle. Over a period of years of use in a vehicle, these remote transmitters are lost, broken, become worn, dirty, and their mounting to a visor is somewhat unsightly. Also, they pose a safety hazard if not properly secured within a vehicle.
To solve some of these problems, U.S. Pat. No. 4,247,850 discloses a remote transmitter incorporated into a vehicle's visor and U.S. Pat. No. 4,447,808 discloses a remote transmitter incorporated in the vehicle's rearview mirror assembly. Incorporating a remote transmitter permanently in a vehicle accessory requires the purchasing and installation of an associated receiving unit tuned to the same frequency as the transmitter and responsive to its modulation scheme and code in the vehicle owner's home. Vehicle owners who already own a garage door receiving unit are reluctant to purchase a new receiving unit associated with the remote transmitter permanently incorporated in their vehicle. Moreover, if a vehicle owner purchases a new car it is likely the owner would have to replace the garage door receiver with another one associated with the built-in remote transmitter in the new vehicle.
U.S. Pat. No. 4,241,870 discloses a housing built in an overhead console of a vehicle for removably receiving a specially adapted garage door remote transmitter such that the vehicle's battery provides operating power to the remote transmitter. Thus, when a vehicle owner purchases a new car, the remote transmitter may be removed from the old car and placed in the new car if it includes a console for receiving the transmitter. The housing in the overhead console is not mechanically adapted to receive existing garage door remote transmitters, and therefore, the vehicle owner must purchase a specially adapted remote transmitter and an associated receiver.
U.S. Pat. No. 4,595,228 discloses an overhead console for a vehicle having a compartment with a drop down door for removably receiving an existing garage door remote transmitter. The door includes a panel which is movable for actuating the switch of the stored existing remote transmitter. A problem with this approach, however, is that remote transmitters for garage door openers vary considerably in shape and size and it is difficult to provide a housing that is mechanically compatible with the various brands of remote transmitters.
To solve all of the above problems, a trainable transceiver has been developed for incorporation in a universal garage door opener to be permanently located in a vehicle and powered by the vehicle's battery. This trainable transceiver is capable of learning the radio frequency, modulation scheme, and data code of an existing portable remote RF transmitter associated with an existing receiving unit located in the vehicle owner's garage. Thus, when a vehicle owner purchases a new car having such a trainable transceiver, the vehicle owner may train the transmitter to the vehicle owner's existing clip-on remote RF transmitter without requiring any new installation in the vehicle or home. Subsequently, the old clip-on transmitter can be discarded or stored.
If a different home is purchased or an existing garage door opener is replaced, the trainable transceiver may be retrained to match the frequency and code of any new garage door opener receiver that is built into the garage door opening system or one which is subsequently installed. The trainable transceiver can be trained to any remote RF transmitter of the type utilized to actuate garage door opening mechanisms or other remotely controlled devices such as house lights, access gates, and the like. It does so by learning not only the code and code format (i.e., modulation scheme), but also the particular RF carrier frequency of the signal transmitted by any such remote transmitter. After being trained, the trainable transceiver actuates the garage door opening mechanism without the need for the existing separate remote transmitter. Because the trainable transceiver is an integral part of a vehicle accessory, the storage and access difficulties presented by existent "clip-on" remote transmitters are eliminated. Such a trainable transceiver is disclosed in U.S. Pat. No. 5,442,340, issued on Aug. 15, 1995 and entitled "TRAINABLE RF TRANSMITTER INCLUDING ATTENUATION CONTROL," U.S. Pat. No. 5,479,155, issued on Dec. 26, 1995 and entitled "VEHICLE ACCESSORY TRAINABLE TRANSMITTER," and U.S. Pat. No. 5,475,366, issued on Dec. 12, 1995 and entitled "ELECTRICAL CONTROL SYSTEM FOR VEHICLE OPTIONS."
These trainable transmitters include a receiver having an antenna for receiving an RF activation signal from a remote control transmitter, a signal generator for generating a reference signal having a frequency selected by a microcontroller, and a mixer for mixing the reference signal with the received activation signal to output a signal having the data encoded in the received RF activation signal and having a frequency equal to the difference between the carrier frequency of the received RF activation signal and the frequency of the reference signal. Such trainable transmitters further include a narrow bandpass filter for blocking all signal components output from the mixer except for any signal component having a predefined frequency falling within the bandpass of the bandpass filter. Additionally, these trainable transmitters include an integrator for demodulating the output of the bandpass filter to supply the data code to the microcontroller. By varying the frequency of the signal generator step-by-step while monitoring the output of the integrator for a data code, the microcontroller can identify the frequency and code of a received RF activation signal having an unknown carrier frequency falling in a prefixed frequency band of, for example, from 200 to 400 MHz. Thus, the receiver of such trainable transmitters has a narrow pass bandwidth centered about a central frequency, which may be dynamically adjusted by controlling the frequency of the signal generator. Such a narrow pass bandwidth assures that the carrier frequency of a received RF activation signal is precisely identified.
Such trainable transceivers typically provide an indication to the operator using an LED or the like, when a training mode is begun and when it is completed. Such systems have not, however, provided any feedback to the operator indicating that an original transmitter signal having a valid frequency is being received at the beginning of the training sequence. Because the step-by-step dynamic adjustment of the central frequency of the receiver that is required to identify the carrier frequency during the training sequence may take some time, it would be desirable to provide an early indication to the user when and if the trainable transmitter is receiving a signal from the original remote transmitter. Also, it would be desirable for the trainable transmitter to terminate a training sequence if it is not receiving a signal from the original transmitter within a predetermined time period. However, the narrow pass bandwidth of the receiver would suggest that the only way to determine whether a signal is being received, is to adjust the central pass frequency step-by-step. Thus, the very nature of such trainable transmitters suggests that any attempt to provide an early feedback to the user would be unnecessary since the trainable transmitter would have finished the training sequence seconds after the microcontroller would have detected the presence of data code at a selected reference frequency.
Further, if such trainable transmitters utilize a small dynamically tunable loop antenna for receiving signals during the training sequence, the relatively narrow bandwidth of the loop antenna would also suggest that it would not be possible to quickly determine whether a signal is being transmitted by an original remote control without sequentially stepping through the tuning frequencies of the tunable antenna.
SUMMARY OF THE INVENTION
The present invention solves the above problems and provides a trainable transmitter capable of providing a user with an early indication during a training sequence that signal is being received from an original remote transmitter. Another aspect of the present invention is to provide a trainable transmitter capable of detecting the presence of an RF signal having an unknown carrier frequency within a predefined frequency band at the initiation of a training sequence. Yet another aspect of the present invention is to terminate a training sequence when the presence of an RF signal from an original remote transmitter has not been detected within a predetermined time period. Another feature of the present invention is to provide a trainable transmitter having a dynamically tunable antenna that is capable of providing a user with an early indication during a training sequence that signal is being received from an original remote transmitter.
To achieve these and other advantages, and in accordance with the purpose of the invention as embodied and described herein, the trainable transmitter of the present invention comprises an antenna for receiving an RF signal from a remote control transmitter used to remotely actuate a device, the RF signal having signal characteristics including a data code and an RF carrier frequency that is initially an unknown frequency within a predefined range between a first frequency and a second frequency. The trainable transmitter further includes a tunable RF circuit coupled to the antenna for receiving RF signals received by the antenna. The RF circuit has a data output terminal and a frequency control terminal for receiving frequency control signals. The RF circuit is selectively tuned to a frequency corresponding to a frequency control signal applied to the frequency control terminal and provides any data code present in a received RF signal at the data output terminal whenever the RF carrier frequency of the received RF signal corresponds to the frequency at which the RF circuit is tuned. The trainable transmitter also includes a control circuit coupled to the frequency control terminal and to the data output terminal of the RF circuit. The control circuit is operative in a training mode and in an operating mode. When in the training mode, the control circuit initiates a training sequence by applying a first frequency control signal to the frequency control terminal to tune the RF circuit to the first frequency and by subsequently applying a second frequency control signal to the frequency control terminal to tune the RF circuit to the second frequency. During the jump from the first frequency to the second frequency, the RF circuit supplies a detection signal at the data output terminal representing the presence of a received RF signal having an RF carrier frequency within the predefined frequency range. In response to the detection signal, the control circuit continues the training sequence by identifying the RF carrier frequency and code of the received RF signal. Preferably, the trainable transmitter additionally includes an indicator light coupled to the control circuit for providing a user with an indication that an RF signal is being received within the predefined frequency range in response to an activation signal received from the control circuit.
The trainable transmitter of the present invention may also include a dynamically tunable antenna coupled to, and controlled by, the control circuit in correspondence with the control of the frequency of the signal supplied to the receiver by the signal generator. At the initiation of a training sequence, the control circuit causes the tuned frequency of both the receiver and the antenna to be swept simultaneously thereby causing both the antenna and the receiver to momentarily pass signals with frequencies within the frequency band of interest.
These and other features, objects, and benefits of the invention will be recognized by those who practice the invention and by those skilled in the art, from reading the following specification and claims together with reference to the accompanying drawing figures.

BRIEF DESCRIPTION OF THE DRAWINGS
In the drawings:
FIG. 1 is a fragmentary perspective view of a vehicle interior having an overhead console for housing the trainable transceiver of the present invention;
FIG. 2 is a perspective view of a trainable transceiver of the present invention;
FIG. 3 is a perspective view of a visor incorporating the trainable transceiver of the present invention;
FIG. 4 is a perspective view of a mirror assembly incorporating the trainable transceiver of the present invention;
FIG. 5 is an electrical circuit diagram partly in block and schematic form of the trainable transceiver of the present invention;
FIG. 6A is an electrical circuit diagram partly in block and schematic form showing details of the circuit shown in FIG. 5;
FIG. 6B is an electrical circuit diagram in schematic form showing the details of the voltage controlled oscillator shown in FIG. 6A;
FIG. 6C is an electrical circuit diagram in schematic form showing the details of the mixer, bandpass filter, amplifier, and integrator shown in FIG. 6A;
FIG. 7 is an electrical circuit diagram partly in block and schematic form showing the details of the phase-locked loop shown in FIG. 6A;
FIG. 8A is a flow diagram of the programming for the microcontroller shown in FIGS. 5 and 6A;
FIG. 8B is a detailed flow diagram of the signal transmitting routine shown in FIG. 8A;
FIGS. 9A-9G is a flow diagram of the training sequence performed by the microcontroller shown in FIGS. 5 and 6A;
FIG. 10 is a flow diagram of a data verification subroutine utilized during the training programming performed by the microcontroller shown in FIGS. 5 and 6A;
FIGS. 11A-11B is a flow diagram of an encoding subroutine utilized by the training programming performed by the microcontroller shown in FIGS. 5 and 6A;
FIG. 12 is a flow diagram of a condensing subroutine utilized in the training programming performed by the microcontroller shown in FIGS. 5 and 6A;
FIG. 13 is a flow diagram of a rolling code identification (RCID) and training subroutine utilized in the training program performed by the microcontroller shown in FIGS. 5 and 6A; and
FIG. 14 is a graphic representation of a vehicle and a typical transmission pattern of a transmitter installed in the vehicle.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 2 shows a trainable transceiver 43 of the present invention. Trainable transceiver 43 includes three push button switches 44, 46, and 47, a light emitting diode (LED) 48, and an electrical circuit board and associated circuits that may be mounted in a housing 45. As explained in greater detail below, switches 44, 46, and 47 may each be associated with a separate garage door or other device to be controlled. Trainable transceiver housing 45 is preferably of appropriate dimensions for mounting within a vehicle accessory such as an overhead console 50 as shown in FIG. 1. In the configuration shown in FIG. 1, trainable transceiver 43 includes electrical conductors coupled to the vehicle's electrical system for receiving power from the vehicle's battery. Overhead console 50 includes other accessories such as map reading lamps 52 controlled by switches 54. It may also include an electronic compass and display (not shown).
Trainable transceiver 43 may alternatively be permanently incorporated in a vehicle accessory such as a visor 51 (FIG. 3) or a rearview mirror assembly 53 (FIG. 4). Although trainable transceiver 43 has been shown as incorporated in a visor and mirror assembly and removably located in an overhead console compartment, trainable transceiver 43 could be permanently or removably located in the vehicle's instrument panel or any other suitable location within the vehicle's interior.
System Hardware
FIG. 5 shows the electrical circuit of trainable transceiver 43 in block and schematic form. Trainable transceiver 43 includes a conventional switch interface circuit 49 connected to one terminal of each of the push button switches 44, 46, and 47, which each have their remaining terminal coupled to ground. Interface circuit 49 couples signal information from switches 44, 46, and 47 to the input terminals 62 of a microcontroller 57, which is part of trainable transceiver circuit 55. A power supply 56 is conventionally coupled to the vehicle's battery 60 through connector 61 and is coupled to the various components of trainable transceiver circuit 55 for supplying their necessary operating power in a conventional manner. In addition to microcontroller 57, transceiver circuit 55 includes a radio frequency (RF) circuit 58 coupled to microcontroller 57 and to an antenna 59.
As described above, switches 44, 46, and 47 may each correspond to a different device to be controlled such as different garage doors, electrically operated access gates, house lighting controls or the like, each of which may have their own unique operating RF frequency, modulation scheme, and/or security code. Thus, switches 44, 45, and 47 correspond to a different radio frequency channel for trainable transceiver 43. Once the RF channel associated with one of switches 44, 46, and 47 has been trained to an RF activation signal B transmitted from a portable, remote transmitter 65 associated with a garage door opener 66 (for example), transceiver 43 will then transmit an RF signal T having the same characteristics as activation signal B to actuate a device such as garage door opener 66 when the corresponding switch (44, 46, 47) is momentarily depressed. Thus, by identifying and storing the carrier frequency, modulation scheme, and data code of a received RF activation signal B originating from a remote transmitter 65, transceiver 43 may subsequently transmit an RF signal T having the identified characteristics of RF signal B that are necessary to activate a device such as garage door opener 66. Each RF channel may be trained to a different RF signal B such that a plurality of devices in addition to a garage door opener 66 may be activated by depressing a corresponding one of switches 44, 46, and 47. Such other devices may include additional garage door openers, a building's interior or exterior lights, a home security system, or any other household appliance capable of receiving an RF control signal.
Microcontroller 57 includes data input terminals 62 for receiving signals from switch interface 49 indicative of the closure states of switches 44, 46, and 47. An additional input terminal 62a may be provided for receiving input data from other sources, such as a serial connector terminal for receiving downloaded information, a voice actuated circuit, or from a vehicle data entry system. An example of such a vehicle data entry system is disclosed in allowed U.S. Pat. No. 5,555,172 entitled USER INTERFACE FOR CONTROLLING ACCESSORIES AND ENTERING DATA IN A VEHICLE, and filed on Aug. 22, 1994, the disclosure of which is incorporated by reference herein. Input terminal 62a is provided to receive data input by the user directly or from some other source. Such data may include a programming command, a cryptographic key, an identification of the make and/or model of the remote transmitter 65, or the cryptographic algorithm itself.
Microcontroller 57 additionally has an output coupled to an LED 48, which is illuminated when one of switches 44, 46, and 47 is closed. Microcontroller 57 is programmed to provide signals to LED 48 to slowly flash when the circuit enters a training mode for one of the RF channels associated with switches 44, 46, and 47, to rapidly flash when a channel is successfully trained, and to slowly flash with a distinctive double blink to prompt an operator to re-actuate the remote transmitter. Alternatively, LED 48 may be a multi-color LED that changes color to indicate when a channel is successfully trained or to prompt the operator to re-actuate the remote transmitter. Once trainable transceiver 43 is trained, LED 48 lights continuously upon action of a switch 44, 46, or 47 during its depression to indicate to the user that the transceiver is transmitting a signal T.
Microcontroller 57 may also include a terminal 62b for coupling to a display device 64, such as that disclosed in the above-mentioned U.S. Pat. No. 5,555,172, to provide a user interface for prompting a user to perform certain operations during the training and operation of the trainable transceiver. For example, microcontroller 57 may display a message to a user to perform a re-synchronization training or transmitting operation if required to synchronize the trainable transceiver with the receiver of the garage door opening mechanism 66. Further, microcontroller 57 may also display a message prompting the user to re-actuate a transmitting switch on remote transmitter 65 to determine whether the transmitting code has changed to thus identify the presence of a variable code. Additionally, microcontroller 57 may display a message indicating that the received signal was successfully trained and to display additional messages useful in leading the operator through a training sequence.
FIG. 6A shows the details of transceiver circuit 55, which includes microcontroller 57, RF circuit 58, and antenna 59. Microcontroller 57 includes a non-volatile memory (NVM) and a random access memory (RAM) and may include any suitable commercially available integrated circuit such as a MC6805P4 integrated circuit available from Motorola.
Antenna 59 is preferably a dynamically tunable antenna including a small loop antenna 70 having one terminal coupled to the anode of a first varactor diode 71a, which has its cathode coupled to the cathode of a second varactor diode 71b, which has its anode coupled to ground. Varactor diodes 71a and 71b change the impedance characteristics of loop antenna 70 in response to a control voltage applied between the cathodes of varactor diodes 71a and 71b and thereby changes the resonant frequency of small loop antenna 70. This control voltage is determined by microcontroller 57, which provides an antenna control digital output signal to the input terminals 72' of a digital-to-analog (D/A) converter 72 that is coupled to the cathodes of varactor diodes 71a and 71b. By using an antenna that is dynamically tuned, one may program microcontroller 57 to selectively adjust the resonant frequency of antenna 59 to maximize its transmission and reception characteristics for each particular frequency at which an RF signal is transmitted or received.
Thus, antenna 59 may be dynamically tuned to maximize the efficiency at which antenna 59 converts a received electromagnetic RF signal to an electrical signal during a receive mode and the efficiency at which antenna 59 radiates a transmitted electromagnetic RF signal in a transmit mode. Additionally, when antenna 59 is dynamically tuned to a resonant frequency corresponding to the carrier frequency of the transmitted signal, antenna 59 can remove unwanted harmonics from the signal to be transmitted. In this manner, tunable antenna 59 acts as a bandpass filter having a variable central frequency corresponding to the transmitted carrier frequency. Preferably, loop antenna 70 is disposed perpendicular to the vehicle's roof to take advantage of the reflective properties of the roof thereby increasing the transmission range and sensitivity of the transceiver when located in a vehicle. The manner in which microcontroller 57 controls antenna 59 is described below in connection with the flow diagram shown in FIG. 8A.
Coupled to antenna 59 for transmitting learned RF control signals is an RF circuit 58, which includes a voltage controlled oscillator (VCO) 73 having a control input terminal coupled to a data output terminal of microcontroller 57 for controlling the frequency output by VCO 73. The detailed construction of a VCO suitable for use in the present invention is shown in FIG. 6B.
VCO 73 includes two portions--an oscillator 103, which outputs a sinusoidal signal that may be modulated by ASK data, and an LC resonator 104, which provides a variable frequency resonating signal to oscillator 103. Oscillator 103 includes an oscillating transistor 110 having a collector coupled to a positive source voltage V.sub.EE, a base coupled to a first terminal of a capacitor 112, and an emitter coupled to ground via a switching transistor 114. A buffer transistor 116 has a base coupled to a second terminal of capacitor 112, a collector coupled to a positive source voltage V.sub.EE, and an emitter coupled to a first terminal of a resistor 118, which has a second terminal connected to ground via switching transistor 114. Switching transistor 114 has its base coupled to receive ASK data from microcontroller 57 such that switching transistor 114 selectively couples the emitters of transistors 110 and 116 to ground. Thus, switching transistor 114 selectively modulates the signal at VCO output 73' provided at the emitter of buffer transistor 116.
LC resonator 104 includes a first coupling capacitor 120 having one terminal coupled to the base of oscillating transistor 110 and another terminal coupled to a first terminal of an inductor 122. A second coupling capacitor 124 has one terminal coupled to the emitter of oscillating transistor 110 and another terminal coupled to the cathodes of first and second varactor diodes 126 and 128. The anode of first varactor diode 126 is coupled to the first terminal of inductor 122 and first coupling capacitor 120 and the anode of second varactor diode 128 is coupled to a second terminal of inductor 122, which is coupled to ground. Varactor diodes 126 and 128 and inductor 122 form a resonating LC circuit having a variable resonant frequency that is varied by varying the voltage applied to the cathodes of varactor diodes 126 and 128 via a resistor 130 coupled to a voltage control terminal 73".
RF circuit 58 further includes a variable gain amplifier (VGA) 74 having an input coupled to an output of VCO 73 applies signals to the input of a transmit amplifier 77 through a coupling circuit 76. An output capacitor 78 is coupled between an output of transmit amplifier 77 and loop antenna 70.
RF circuit 58 additionally includes a capacitor 80 for coupling a mixer 79 to antenna 59. A buffer amplifier 81 has an input coupled to an output of VCO 73 and applies signals therefrom to one input of mixer 79 having its remaining input terminal coupled to capacitor 80 for receiving signals from antenna 59. A bandpass filter 82 has an input coupled to receive signals from an output of mixer 79 and has an output coupled to an input of an amplifier 83. Bandpass filter 82 preferably has a narrow bandwidth and a center frequency of 3 MHz to pass a data signal having a 3 MHz frequency component while blocking all other signals output from mixer 79.
The output of amplifier 83 is coupled to the input of an integrator 84 having an output coupled to a data input terminal of microcontroller 57. Integrator 84 integrates and rectifies the signal supplied from amplifier 83 to remove the 3 MHz frequency component from the signal and to provide a demodulated representation of the data code of the remote transmitter to microcontroller 57.
In addition, RF circuit 58 includes a serial port and control logic circuit 75 having input terminals coupled to a serial data address (SDA) line 75' and a serial control logic (SCL) line 75". VCO output 73' is also coupled to an input of buffer 91 having its output coupled to a feedback input of a phase-locked loop circuit 85. A reference oscillator including a crystal 86 having first and second terminals coupled across an amplifier 87 and to comparator amplifier 88. The reference oscillator 86 is thus coupled to a clock input of controller 57 and to phase-locked loop circuit 85 for supplying a reference signal to be compared with the signal output from VCO 73.
RF circuit 58 also includes a low pass filter 89 having an input terminal coupled to an output 85' of phase-locked loop circuit 85 for holding a control voltage that is applied to a voltage control terminal 73" of VCO 73 via a voltage control buffer 90.
VCO 73 outputs an RF signal having a frequency that may be adjusted by varying the voltage applied to its voltage control terminal 73". The RF signal output from VCO 73 is modulated with amplitude shift-keyed (ASK) data provided by microcontroller 57 when operating in a transmit mode. The modulated RF output signal of VCO 73 is applied to VGA 74. VGA 74 variably amplifies the modulated RF signal supplied from VCO 73 in proportion to a GAIN control signal provided by serial port and control logic circuit 75 in response to control signals sent by microcontroller 57 over the SCL line 75" and the SDA line 75'. VGA 74 may be implemented with a pair of differential amplifiers and a digitally controlled current diverter that diverts current from one of the differential amplifiers to the other differential amplifier thereby selectively decreasing the gain of VGA 74. As described in greater detail below, the gain level of VGA 74 is determined as a function of the duty cycle and frequency of the signal to be output from VCO 73.
The gain-adjusted output of VGA 74 is supplied to coupling circuit 76, which filters undesirable harmonics from the RF signal output from VGA 74. Preferably, coupling circuit 76 includes a 22 ohm resistor coupled in series with a 470 pF capacitor. The filtered output signal of coupling circuit 76 is then provided to transmit amplifier 77, which amplifies the filtered output to an appropriate transmission level. The output of transmission amplifier 77 is provided to antenna 59 via output capacitor 78, which preferably has a capacitance of 470 pF.
Previous systems have used a variable attenuator to reduce the power of the signal output from a relatively high power VCO. However, such systems tend to transmit undesirable harmonic components with the desired activation signal. It is desirable to remove these harmonic components from the RF signal output by VCO 73 because the output energy level of such harmonic components transmitted from antenna 59 must be considered in computing an allowable output energy level under FCC guidelines. In other words, the greater the amplitude of harmonic frequency components output from antenna 59, the lower the transmitted amplitude of the desired carrier frequency component may be. Thus, the use of VGA 74, coupling circuit 76, transmit amplifier 77 and tunable antenna 59, which amplify and filter a low power RF signal output from VCO 73, offers a distinct advantage over a transmission circuit utilizing a variable attenuator for attenuating a relatively high power output RF signal from a VCO.
Mixer 79 mixes received RF signals from antenna 59 with a reference RF signal generated by VCO 73 and supplied to mixer 79 through buffer 81. The output of mixer 79 includes several signal components including one component representing the received RF signal but having a carrier frequency equal to the difference of the carrier frequency of the received RF signal and the frequency of the RF reference signal generated by VCO 73. The output signal of mixer 79 is applied to the input of bandpass filter 82, which preferably has a narrow bandwidth centered about a frequency of 3 MHz such that bandpass filter 82 outputs an encoded data signal only when the frequency of the RF reference signal generated by VCO 73 is 3 MHz above or below the carrier frequency of the received RF signal. Thus, the remaining signal components of the output of mixer 79 are blocked by bandpass filter 82. The encoded output data signal from bandpass filter 82 is amplified by amplifier 83 and integrated by integrator 84 to provide a signal having the same data code as that output from a remote transmitter 65 (FIG. 5).
To prevent transmission of signals during a learning mode, serial port and control logic circuit 75 (FIG. 6A) controls the enablement and disablement of VGA 74 and transmit amplifier 77 by applying a transmit control signal TX. Similarly, serial port and control logic circuit 75 provides a receive control signal RX, which is applied to selectively enable and disable mixer 79, receive buffer 81, amplifier 83, and integrator 84 as shown by the dashed line enable inputs of FIG. 6A.
FIG. 6C shows an electrical schematic of an exemplary mixer 79, bandpass filter 82, amplifier 83, and integrator/rectifier 84. Mixer 79 receives the signal received from antenna 59 via input terminal 140 and the reference signal generated by VCO 73 via terminal 141. The two signals are coupled together and fed to the base of a transistor 143 by a capacitor 142. Transistor 143 has its emitter coupled to ground and its collector coupled to its base by resistor 144. Preferably, capacitor 142 is a 56 pF capacitor and resistor 144 has a resistance of 150 k.OMEGA.. Input ports 140 and 141 are coupled to a power supply bus 145 via a pull-up resistor 146, which preferably has a resistance of 1 k.OMEGA.. Power supply bus 145 is selectively powered to the voltage V.sub.EE by a transistor 182 having its base connected to terminal 186 to receive a receive control signal RX from microcontroller 57. A resistor 184 of preferably 2 k.OMEGA. is connected between the emitter and base of transistor 182. Power supply bus 145 is thereby brought up to the +V.sub.EE voltage when the receive control signal RX is received from microcontroller 57. Power supply bus 145 is coupled to ground via two parallel capacitors 156 and 166, which preferably have a capacitance of 0.1 .mu.F. Mixer 79 further includes a resistor 150, capacitor 152, and an inductor 154 all coupled in parallel between power supply bus 145 and an output terminal 157 of mixer 79, which is provided from the collector of transistor 143 via a resistor 148. Preferably, resistor 148 has a resistance of 4.3 k.OMEGA., resistor 153 has a resistance of 7.5 k.OMEGA., capacitor 152 has a capacitance of 180 pF, and inductor 154 has an inductance of 15 .mu.H. Although a specific preferred configuration is described, mixer 79 may be of any conventional construction provided such a mixer is capable of mixing high frequency RF signals.
Bandpass filter 82 preferably includes a coupling capacitor 158 having one terminal connected to the output terminal 157 of mixer 79 and having its other terminal connected to the filter output terminal 161, which is connected to ground by an inductor 160. Preferably, capacitor 158 is a 22 pF capacitor, and inductor 160 has an inductance of 15 .mu.H to provide a band pass centered at 3 MHz, although other configurations may be used.
The output terminal 161 of filter 82 is coupled to amplifier 83 by two series capacitors 162 and 164, which form the input of amplifier 83. Amplifier 83 further includes a transistor 168 having its base coupled to the junction of capacitors 162 and 164, having its emitter coupled to ground, and having its collector coupled to its base via a resistor 170 and also coupled to power supply bus 145 via resistor 172. Additionally, amplifier 83 includes a resistor 174 leaving one terminal coupled to the collector of transistor 168 and its remaining terminal coupled to the emitter of transistor 168 by a capacitor 176. The output of amplifier 83 is provided at the node 175 between resistor 174 and capacitor 176. Preferably, capacitor 162 has a capacitance of 150 pF, capacitor 164 has a capacitance of 180 pF, resistor 170 has a resistance of 39 k.OMEGA., resistor 172 has a resistance of 820 k.OMEGA., resistor 174 has a resistance of 150 k.OMEGA., and capacitor 176 has a capacitance of 56 pF. Although a specific preferred configuration of amplifier 83 is described, it will be understood that other configurations may be used.
Integrator/rectifier 84 includes a capacitor 178 coupled at one end to the output node 175 of amplifier 83 and coupled at its other end to power supply bus 145 via a resistor 180 and to the anode of a diode 188. Integrator/rectifier 84 further includes an integrating capacitor 190 and a resistor 192 connected in parallel between the cathode of diode 188 and ground. Further, integrator/rectifier 84 includes a coupling capacitor 194 coupled between the cathode of diode 188 and the output terminal 196 to provide an output signal which is applied to a data input port of microcontroller 57 (FIG. 6A). Preferably, capacitor 178 has a capacitance of 2200 pF, resistor 180 has a resistance of 56 k.OMEGA., capacitor 190 has a capacitance of 180 pF, resistor 192 has a resistance of 1 M.OMEGA., and capacitor 194 has a capacitance of 1 .mu.F. The specific preferred configuration of integrator/rectifier 84 is described for purposes of example only as other configurations may be used.
The data signal output from integrator 84, which is typically amplitude shift-keyed (ASK) data, also has the same data format as the RF activation signal B transmitted by remote transmitter 65. The ASK data output from integrator 84 is provided to microcontroller 57 for further processing and storage. The manner in which microcontroller 57 processes and stores this ASK data and controls RF circuit 58 is described in greater detail below following a description of the portion of RF circuit 58 that provides a voltage control signal to VCO 73.
The portion of RF circuit 58 that supplies the voltage control signal to VCO 73 includes phase-locked loop circuit 85, reference oscillator 86, amplifier 87, comparator amplifier 88, low pass filter 89, voltage control buffer 90, and a VCO output buffer 91. The manner in which this portion of RF circuit 58 operates is described with reference to FIG. 7, which shows the detailed construction of the phase-locked loop circuit 85. Phase-locked loop circuit 85 includes a divide-by-R register 92 having an input coupled to the second terminal of reference oscillator 86. A divide-by-N register 93 has an input coupled to the output of VCO output buffer 91. The outputs of registers 92 and 93 are coupled to input terminals of a phase/frequency detector 94 having an output coupled to the input of a control logic circuit 95. Control logic circuit 95 in turn has a pair of terminals coupled to inputs of a sink/source switch circuit 98 having an output terminal coupled to the input of low pass filter 89. Preferably, low pass filter 89 includes a 560.OMEGA. resistor coupled to the output of phase-locked loop circuit 85, a 1.2 .mu.F capacitor coupled in series with the 560.OMEGA. resistor, and a 0.1 .mu.F capacitor connected in parallel with the 560.OMEGA. resistor and the 1.2 .mu.F capacitor.
The primary purpose of phase-locked loop circuit 85 is to compare the frequency of the RF signal output by VCO 73 with that of reference oscillator 86 and to control the voltage applied to the voltage control terminal of VCO 73 such that the frequency of the RF signal output by VCO 73 has a predetermined relationship to the frequency of reference oscillator 86. The predetermined relationship between the frequencies of these respective signals is a ratio of two variables R and N supplied to divide-by-R register 92 and divide-by-N register 93, respectively, from microcontroller 57 via serial port and control logic circuit 75. Mathematically, the relationship between the frequency f.sub.VCO of the RF signal output by VCO 73 and the frequency f.sub.REF of the signal output by reference oscillator 86 may be expressed as follows: ##EQU1## where f.sub.REF is a constant value of, for example, 4 MHz. Thus, using f.sub.REF =4 MHz and R=4, the frequency f.sub.VCO may be controlled to be equal to N MHz. If f.sub.REF and R constant are held constant, increasing the value N increases the frequency f.sub.VCO accordingly. If the value of R is increased, the frequency f.sub.VCO may be more finely controlled. On the other hand, the smaller the value of R, the greater the range in which f.sub.VCO may operate. Preferably, the values of R and N are provided as eight bits of data.
The outputs of divide-by-R register 92 and divide-by-N register 93 are supplied to phase/frequency detector 94, which compares the frequency of the signal output from divide-by-N register 93 with the frequency output from divide-by-R register 92 and provides output pulses corresponding to the difference in frequency. Phase/frequency detector 94 may be constructed in any conventional manner. If these respective frequencies are the same, phase/frequency detector 94 outputs pulsed control signals to switches 99 and 100 of sink/source switch circuit 98 such that both switches 99 and 100 remain open. When both of switches 99 and 100, which may be solid state switches such as CMOS or bipolar transistors, of sink/source switch circuit 98 are both held open, the voltage applied to the voltage control terminal of VCO 73 is held constant by buffer 90 and the voltage stored by the capacitors in low pass filter 89.
When the frequency of the signal output from divide-by-N register 93 is less than the frequency of the signal output from divide-by-R register 92, phase/frequency detector 94 supplies pulsed control signals to switches 99 and 100 causing switch 99 to close and switch 100 to remain open. When switch 99 is closed, a voltage V.sub.CC of five volts, for example, is applied to the capacitor of low pass filter 89 thereby increasing the voltage applied to the voltage control terminal of VCO 73. The increased voltage at the voltage control terminal of VCO 73 causes VCO 73 to increase the frequency of its output RF signal, which, in turn, increases the frequency of the signal output by divide-by-N register 93. When the frequencies of the signals output from divide-by-R register 92 and divide-by-N register 93 are the same, phase/frequency detector 94 provides control signals to switches 99 and 100 to open switch 99 and to maintain switch 100 in an open position.
If the frequency of the signal output from divide-by-N register 93 is greater than the frequency of the signal output from divide-by-R register 92, phase/frequency detector 94 outputs control signals to switches 99 and 100 causing switch 99 to remain open and switch 100 to close. When switch 100 is closed, the capacitor in low pass filter 89 is connected to ground and, thus, discharges. The discharging of the capacitor in low pass filter 89 decreases the voltage applied to the voltage control terminal of VCO 73, which causes VCO 73 to reduce the frequency of the output RF signal. Thus, the frequency of the output signal from divide-by-N register 93 is decreased until phase/frequency detector 94 determines that the frequencies of the signals output from divide-by-R register 92 and divide-by-N register 93 are the same.
Control logic circuit 95 is provided to selectively connect and disconnect phase/frequency detector 94 from sink/source switch circuit 98 in accordance with the logic level of the ASK data read from the memory of microcontroller 57 during a transmit mode. During a transmit mode, microcontroller 57 enables and disables VCO 73 using the ASK data stored in its memory for the selected channel in order to modulate the ASK data onto the carrier RF signal generated by VCO 73 for transmitting the learned data code. When VCO 73 is disabled by the ASK data, the frequency of the signal output from VCO 73 as detected by phase-locked loop circuit 85 falls to zero. If appropriate means were not provided in phase-locked loop circuit 85, phase/frequency detector 94 would control sink/source switch circuit 98 such that the frequency control voltage applied to VCO 73 is significantly increased when VCO 73 is disabled. Then, upon being enabled, VCO 73 would initially begin transmission at a carrier frequency far exceeding that which is desired. In order to prevent phase-locked loop circuit 85 from dramatically increasing the frequency of VCO 73 during a disabled state, control logic circuit 95 is provided to selectively disconnect phase/frequency detector 94 from sink/source switch circuit 98 when the ASK data is at a level which disables VCO 73.
In order to maintain the phase relationship between the signals output from divide-by-R register 92 and divide-by-N register 93 following a disablement of VCO 73, the ASK data read from the memory of microcontroller 57 during a transmit mode is provided to enable and disable divide-by-R register 92 and divide-by-N register 93 in synchronism with VCO 73, which is also enabled and disabled by the ASK data signal.
RF circuit 58 is preferably incorporated into an application-specific integrated circuit (ASIC) 101 manufactured employing existing integrated circuit technology. In the preferred embodiment shown in FIG. 6A, the following elements are provided on a substrate 102 of ASIC 101: VGA 74; mixer 79; receive buffer 81; amplifier 83; integrator 84; phase-locked loop circuit 85; amplifier 87; comparator 88; voltage control buffer 90; and the oscillator portion 103 of VCO 73. Although coupling circuit 75, transmit amplifier 77, output capacitor 78, input capacitor 80, bandpass filter 82, reference oscillator 86, low pass filter 89, and the LC resonator portion 104 of VCO 73 are not shown as being incorporated into ASIC 101 to avoid including relatively large capacitors within substrate 102, these elements could nevertheless be included in ASIC 101.
System Operation
Having described the electrical circuit elements of transceiver circuit 55, the manner by which microcontroller 57 controls transceiver circuit 55 is now discussed with reference to FIGS. 8A-B, 9A-9G, 10, 11A-11B, 12, and 13. In FIGS. 9A-9G, the transfer ports of the flow diagram are referenced by a letter optionally followed by a number. The reference letter refers to the letter portion of the drawing figure number following FIG. 9. For example, the transfer port labelled C illustrates a transfer in the process to a transfer entry port labelled C in FIG. 9C. The optional number following the reference letter represents one of a plurality of entry points into the process illustrated in the drawing figure corresponding to the reference letter. For example, the transfer port labelled E1 illustrates a transfer to the process shown in FIG. 9E at the transfer entry port labelled E1.
As indicated in the test of block 200 (FIG. 8A), operation begins when one of push button switches 44, 46, and 47 is actuated. Upon detecting that one of switches 44, 46, and 47 has been depressed, microcontroller 57 receives a signal through interface 49 (FIG. 5) and initializes its ports and its random access memory (RAM) as indicated in block 201. Next, the program begins a twenty second timer (block 202) and reads the channel corresponding with the switch 44, 46, and 47 that has been depressed (block 203). Next, the program for microcontroller 57 determines whether the selected channel has been trained (block 204). If the selected channel has previously been trained, microcontroller 57 downloads the data associated with the selected channel into its RAM (block 205), sets the gain of VGA 74 and the frequency to be output by VCO 73, and tunes antenna 59 in accordance with the data associated with the selected channel (block 206). Microcontroller 57 sets the frequency of VCO 73 by providing the appropriate output signals representing values of R and N to divide-by-R register 92 and divide-by-N register 93 via serial port and control logic circuit 75.
Microcontroller 57 sets the gain of VGA 74 by providing a control signal to serial port and control logic circuit 75 over the SCL and SDA lines. The GAIN control signal provided to a gain control input of VGA 74 may consist of a five-bit value, thus providing thirty-two possible gain levels. Because the FCC mandates allow different power levels based upon the duty cycle of the transmitted signal, it is advantageous for the trainable transceiver to be capable of dynamically adjusting the gain of the transmitted signal. Therefore, by providing a number of possible gain levels, transceiver 43 can transmit at the maximum allowable power level for each different frequency and encoded signal it may transmit.
To optimize the appropriate gain level for a given transmitted activation signal, microcontroller 57 first looks at the frequency of the signal to be transmitted to determine its relative power. Assuming that each of the thirty-two possible gain levels correspond to a different integer between 0 and 32, with 0 representing the maximum gain adjustment and 32 representing the minimum gain adjustment, microcontroller 57 selects an initial gain level based upon the frequency of the signal to be transmitted. For example, microcontroller 57 may select an initial gain level of 5 for a strong powered signal and select an initial gain level of 0 for a relatively weak powered signal. Then, microcontroller 57 determines the duty cycle of the code by taking a predetermined number of total samples of the code within a predetermined period of time, counting the number of samples of the code having a high logic level, multiplying the counted number of samples having a high logic level by a predefined constant to determine a product, and dividing the product by the predetermined number of total samples. Microcontroller 57 adjusts the selected initial gain level based upon the duty cycle. For example, if the initial gain level is 5, microcontroller 57 adjusts the gain level to a level falling between 5 and 32 where the lowest gain level (32) corresponds to the highest duty cycle and the highest gain level (5) not exceeding the initial gain level corresponds to the lowest duty cycle. Microcontroller 57 may also select a gain level based upon a determination of whether the data code is fast or slow. An example of how a duty cycle of a code signal may be determined and an output power level may be selected based upon the duty cycle and frequency of the signal to be transmitted is disclosed in U.S. Pat. No. 5,442,340, the disclosure of which is herein incorporated by reference. The manner by which microcontroller 57 determines that the data code provided in the received activation signal is fast or slow is described below.
The gain of VGA 74 preferably may be varied between 15 and 20 dB, and transmit amplifier 77 preferably has a gain of 25 dB. Together, VGA 74 and transmit amplifier 77 provide a variable gain of 10 dB. Preferably, the output power of transceiver 43 is between 0 and 5 dBm.
Microcontroller 57 tunes antenna 59 by providing antenna control data to D/A converter 72. The antenna control data preferably has an eight-bit value, which may be computed from the frequency of VCO 73 or read from a table including a list of eight-bit values associated with various frequencies that may be output from VCO 73. In general, the voltage output from D/A converter 72 is controlled to vary from 0.5 to 4.5 V linearly with respect to a 220 to 440 MHz frequency range. Thus, each increment in the eight-bit value provided by microcontroller 57 represents about a 15.6 mV increment in the output voltage of D/A converter 72. The eight-bit antenna control data may be previously stored in association with the selected channel or may be computed from the frequency data after the data is read from memory. The capacitance of varactor diodes 71a and 71b vary linearly and inversely to the voltage applied to their cathodes. For example, varactor diodes 71a and 71b may have a capacitance of 14 pF when the applied voltage is 0.5 V and a capacitance of 2.4 pF when the applied voltage is 4.5 V. In this manner, small loop antenna 70, which has a relatively small bandwidth for receiving and transmitting signals, may be tuned to have a resonant frequency matching the carrier frequency of a transmitted or received signal such that it more efficiently receives an RF activation signal from a remote transmitter and radiates the RF transmit signal provided from transmit amplifier 76. By providing the capability of dynamically tuning antenna 59 and varying the gain of the output signal as applied to the cathodes of varactor diodes 71a and 71b through output capacitor 78, trainable transceiver circuit 55 maintains a matched impedance of antenna 59 and the output impedance of RF circuit 58.
After setting the gain of VGA 74, the frequency of VCO 73, and the tuning of antenna 59 as indicated in block 206 (FIG. 8A), the microcontroller 57 determines whether the code for the selected channel is a fixed code or a variable code (block 207). This determination may be made based upon the setting of a flag at the time the activation signal is learned. If the code is a fixed code, microcontroller 57 reads the data code stored in memory in association with the selected channel (block 208) and provides this ASK data to VCO 73 and phase-locked loop circuit 85 to modulate the RF signal generated by VCO 73 by disabling and enabling VCO 73 with the ASK data (block 210). On the other hand, if the code is a variable code, microcontroller 57 will read the data stored for the selected channel that identifies the appropriate cryptographic algorithm, the cryptographic key (if any), and the serial number of the last transmitted code. Next, microcontroller 57 will execute the identified cryptographic algorithm, which may be stored in its NVM or some other memory that is preferably non-volatile, to generate the code to be transmitted to the receiver of the garage door opening mechanism (block 209). If the variable code is a real-time code, microcontroller 57 may read the time from an internal or external clock to determine the appropriate code to transmit based upon the time in a manner defined by the cryptographic algorithm. If more than one transmitter may be used to actuate the garage door, microcontroller 57 will also include an ID tag in the generated code identifying the trainable transceiver as the transmitter from which the activation signal was learned.
After generating or reading the code to transmit, microcontroller 57 instructs serial port and control logic circuit 75 to output a transmit signal TX to VGA 74 and transmit amplifier 77 to enable the transmission of the modulated RF output signal of VCO 73 as indicated by block 210.
The transmit sequence shown generally in FIG. 8A by block 210 is shown in detail in FIG. 8B. The transmitting sequence begins in block 211, with microcontroller 57 setting the frequency of VCO 73 to a frequency that is offset from the learned fundamental carrier frequency F.sub.0 by an offset frequency .DELTA.F below the fundamental learned frequency F.sub.0. Then, in block 212, microcontroller 57 transmits the learned code at this frequency for a predetermined time period before changing the frequency of VCO 73 to the fundamental frequency F.sub.0 as shown in block 213. Microcontroller 57 transmits at the fundamental frequency for the same predetermined time period (block 214) before increasing the frequency by an amount equal to the offset frequency .DELTA.F (block 215) and transmitting at this increased frequency for the predetermined time period (block 216). As will be appreciated by those skilled in the art, the offset frequency .DELTA.F should be selected such that the offset from the fundamental frequency will lie within the receiving bandwidth of the device that receives the transmitted signal. Preferably, the offset frequency .DELTA.F should be large enough to cause a change in the transmission pattern to remove nulls while still remaining within the receiver's bandwidth. With respect to typical garage door opener receivers, the offset frequency .DELTA.F is preferably 500 kHz. The predetermined time period at which signals are transmitted in blocks 212, 214, and 216 at the different frequencies, is preferably one-half second. As can be seen in FIG. 8A, the transmission sequence is repeated for a twenty-second interval. Thus, the sequence shown in FIG. 8B will be repeated over and over until the twenty-second timer has elapsed.
By transmitting at a plurality of different frequencies above, below, and including the fundamental learned carrier frequency, the nulls in the transmission pattern can be minimized and the effective range of the transmitter over all angles of transmission can be increased. As shown in FIG. 14, a transmission pattern 1 associated with the transmitted fundamental learned carrier frequency includes a number of nulls 2. By transmitting two additional signals from transmitter 7 in vehicle 6, that have frequencies offset above and below the fundamental learned carrier frequency, the effect of such nulls 2 may be minimized as shown by the exemplary transmission patterns 3 and 4 associated with these two additional transmitted signals.
While performing the above steps, microcontroller 57 monitors the twenty second timer to determine whether the push button switch that was depressed has been continuously depressed for a twenty second interval (block 217, FIG. 8A). If the twenty second interval has not expired, microcontroller 57 continues to transmit the RF signal associated with the selected channel (block 210). If microcontroller 57 determines in block 217 that the switch that was depressed has been continuously depressed for the twenty second interval, or if microcontroller 57 determines in block 204 that the channel associated with the depressed switch has not been trained, microcontroller 57 begins a training sequence that begins in block 218 (FIG. 9A). Before describing the detailed procedure performed by microcontroller 57 in the training mode, a general overview is provided below.
During a training sequence, microcontroller 57 provides frequency control data representing the values R and N for an initial frequency to phase-locked loop circuit 85 (FIG. 6A), and looks for the presence of received data on an RF transmitted signal B (FIG. 5) which is received by antenna 59, processed through mixer 79, bandpass filter 82, and amplifier 83 and applied to microcontroller 57 from integrator 84. Upon receiving the frequency control data, phase-locked loop circuit 85 provides a frequency control voltage to a frequency control terminal of VCO 73. VCO 73 generates a reference signal having a reference frequency corresponding to the frequency control voltage and provides the reference signal to mixer 79. If the reference frequency has a predetermined relationship to the carrier frequency of the received RF activation signal B, integrator 84 provides the code signal of the received activation signal to microcontroller 57. In the preferred embodiment, the predetermined relationship will exist when the difference between the reference frequency and the carrier frequency of the received activation signal is 3 MHz.
If microcontroller 57 does not receive a code signal from integrator 84 for the initial frequency, microcontroller 57 in the next loop selects another frequency and provides phase-locked loop circuit with frequency control data corresponding to the new frequency. Microcontroller 57 continues to select new frequencies in this manner until a code signal is detected as indicated by a signal from integrator 84. Microcontroller 57 affirms the presence of a code signal using a verification routine, which counts the number of rising edges appearing in any signal received from integrator 84 during a predetermined time interval and determines that data is present when the counted number of rising edges exceeds a threshold level. The verification subroutine is described in greater detail below.
Upon detecting a code signal, which preferably occurs when the reference frequency is 3 MHz below the carrier frequency of the received activation signal, microcontroller 57 stores the frequency control data corresponding to the carrier frequency of the received activation signal, and increases the reference frequency by 3 MHz. Ideally, the code signal should disappear at this frequency, however, if the code signal does not disappear at this frequency, microcontroller 57 attempts to encode the code signal it is still receiving at this frequency in order to determine whether the code signal is merely noise attributable to the code signal detected at the frequency 3 MHz lower or whether the code signal detected at this frequency is more than mere noise.
By attempting to encode the code signal, microcontroller 57 can perform a more rigorous test on the code signal to determine whether the code signal is legitimate. As will be described in greater detail below, microcontroller 57 attempts to encode the code signal using an ENCODE subroutine, which further analyzes the code signal to identify its modulation scheme and stores the code signal in memory using the most appropriate encoding technique for the identified modulation scheme of the code signal. If the ENCODE subroutine can identify the modulation scheme of the code signal and store the code signal, the attempt to encode the code signal is deemed successful.
If the code signal received at this increased frequency, which corresponds to the frequency of the received activation signal, is successfully encoded, microcontroller 57 determines that the code signal received at both the initial frequency and the increased frequency is not legitimate because, based on empirical data, a legitimate code signal should not be encodable at two frequencies 3 MHz apart. Having determined that the code signal at this frequency is not legitimate, the program executed by microcontroller 57 selects a new frequency and repeats the above process until a legitimate code signal is detected.
If a code signal is not detected or if a non-encodable code signal is detected at the frequency 3 MHz above the frequency at which the code signal was first detected, microcontroller 57 increases the frequency another 3 MHz and looks for a code signal. Ideally the code signal that disappeared at the previous frequency will reappear at this increased frequency since it is 3 MHz different than the transmitter frequency B and the frequency difference component output from mixer 79 passes through bandpass filter 82. If the code signal reappears, microcontroller 57 changes the reference frequency to the frequency at which the code signal was first detected (i.e., at 3 MHz below the frequency of the activation signal B), and encodes and stores the code signal. In general, microcontroller 57 stores the code signal by sampling the signal at a relatively high sampling rate such as one sample per 68 microseconds. Different sampling rates may be selected for different code signals based upon detected characteristics to the code format of the received code signal. In this manner, microcontroller 57 may reproduce the code signal during a transmit mode, by reading the stored code signal from memory using the same sampling rate at which it stored the code signal. Alternatively, the data representing the number of consecutive samples of the code signal at high and low logic states may be stored or data representing the number of periods at a particular data frequency may be stored. To double check that the received code signal is legitimate, microcontroller 57 preferably sets a DATPREV flag, returns to the beginning of the training sequence, selects a new, higher frequency, and confirms that the previously detected code signal is legitimate provided a code signal is not detected at this new frequency.
To determine whether the received code may be a variable code, microcontroller 57 may check whether the identified frequency is one used with time-varying codes. Additionally, microcontroller 57 may be able to identify a variable code based upon the number of pulses in the code since variable codes may have a higher number of bits. To confirm the presence of a variable code, microcontroller 57 may prompt the user to re-actuate the transmit button on the remote transmitter and check whether the code included in the second transmitted signal is the same as that in the first. Alternatively, the code may dynamically change within a single actuation of the transmit button on the remote transmitter or the characteristics of the pulses themselves may indicate that the code is a variable code, in which case microcontroller 57 could determine that the received code is a variable code.
If the code in the activation signal is a variable code, microcontroller 57 then examines the characteristics of the activation signal (i.e., the number of bits in the code, the pulse width, the pulse repetition rate, and/or the carrier frequency) to identify the make and model of the remote transmitter. By identifying the make and model of the remote transmitter, microcontroller 57 may then identify and access a prestored cryptographic algorithm corresponding to that used by the remote transmitter and its associated receiver. Next, microcontroller 57 prompts the user to perform any special sequence for re-synchronization of the system. This may be a sequence in which the user causes the remote transmitter to transmit a re-synchronization signal or in which a button is depressed on the receiver of the garage door opening mechanism to accept and re-synchronize on the next transmitted signal. If the sequence involves the transmitter transmitting a re-synchronization signal, the trainable transceiver may subsequently be trained to learn and retransmit the re-synchronization signal.
If the identified cryptographic algorithm requires a cryptographic key, microcontroller 57 will determine the appropriate method of receiving the cryptographic key based upon the identified make and model of the remote transmitter since such methods may vary from one manufacturer to another. If the cryptographic key may be downloaded or transmitted from the remote transmitter, microcontroller 57 will prompt the user to take the appropriate action. If the receiver includes some mechanism for changing its cryptographic key to one randomly or manually generated, microcontroller 57 may randomly generate a cryptographic key and transmit the key to the receiver. If a cryptographic key must be manually entered, microcontroller 57 may receive such information through input terminal 62a from a vehicle data entry system or a voice-actuated circuit. Having provided a general overview of the training sequence, a more detailed description is provided below with reference to FIGS. 9A-9G, 10, 11A, 11B, 12, and 13.
Microcontroller 57 begins the training sequence in block 218 of the program (FIG. 9A) by jumping the frequency represented by the frequency control signals supplied to VCO 73 from the lowest frequency in the frequency band of interest (e.g., 200 MHz) to the highest frequency of the frequency band (e.g., 400 MHz) while looking for the detection of a code received during this rapid transition (block 219). Due to the response time of VCO 73 the output frequency of VCO 73 will not instantaneously change from the lowest to highest frequency in response to the frequency jump. Instead, the output will gradually and continuously vary from the lowest to the highest frequency. If a dynamically tunable antenna is employed for receiving signals during a training sequence, microcontroller 57 will simultaneously jump the frequency to which antenna 59 is tuned from the highest to lowest frequency in block 218. As shown in block 220, microcontroller 57 repeatedly and alternatingly applies high and low frequency control signals to frequency control terminal 73' causing VCO 73 to continuously vary the frequency of its output between the lowest and highest frequencies in the preferred frequency range for a ten-second interval unless a code is detected sooner.
With the VCO 73 described in detail above with reference to FIG. 6B, the response time is approximately five milliseconds to vary from a first frequency of 200 MHz to a second frequency of 400 MHz. Thus, the VCO frequency can be gradually, continuously, and repeatedly swept through the frequency range of interest many times throughout the typical duration of a signal transmitted from a garage door opener transmitter. Because the response time of most mixers is nearly instantaneous relative to the response time of VCO 73, mixer 79 instantaneously outputs signal components including one signal component having a carrier frequency equal to the difference between the carrier frequency of the received RF signal and the frequency of the reference signal output from VCO 73 at that particular instant. As the frequency of VCO 73 gradually varies during the frequency jump, a pulse will be output from bandpass filter 82 each time the VCO frequency is 3 MHz different from the carrier frequency of any received RF signal is the frequency band of interest. The pulses output from bandpass filter 82 are detected by microcontroller 57. If no such pulses are detected in this ten-second interval, microcontroller 57 terminates the training sequence and returns to its default mode to wait until a button is once again pushed. If, on the other hand, a pulse is detected during the jumps between the lowest and highest frequencies, the training sequence is continued as shown in block 221.
Thus, if a signal from the original transmitter is received and is within the predefined frequency band, the presence of this signal will be immediately detected and the training sequence will continue while microcontroller 57 informs the user that a valid original transmitter signal is being received by activating an indicator circuit (e.g., beginning the slow blinking of LED 48, FIG. 5). Further, if a valid signal is not being received, the user will know after ten seconds that a valid signal has not been received since LED 48 will then be extinguished and the training sequence will be terminated.
By jumping the frequency of VCO 73 and tuning antenna 59 in this manner, the need to slowly and discretely step through each frequency within the relatively large frequency band of interest merely to provide the user an indication that a valid signal is being received is avoided. Thus, the time required to initially step through each frequency for this purpose is virtually eliminated and the user receives nearly instantaneous feedback from the indicator that a valid signal is being received.
As shown in block 219, if a signal is detected, the training sequence continues in block 221 with the microcontroller 57 retrieving R and N frequency table and by a frequency 3 MHz below a first frequency provided in a prestored frequency table and by clearing an X register (block 221). Preferably, the frequency table first includes, in increasing value, the known operating frequencies of garage door transmitters that transmit only for a limited duration (i.e., approximately two seconds), such as the older Canadian garage door transmitters. These short duration transmitter frequencies are followed in the frequency table by the frequencies at which other commercially available garage door transmitters are known to operate. The frequencies associated with short duration transmitters are provided first in the frequency table in order to increase the likelihood that a successful train will occur before such a short duration transmitter stops transmitting its RF activation signal. In the event that the RF activation signal transmitted by a garage door transmitter does not have a frequency stored in the frequency table, trainable transceiver 43 will increment an initial frequency at 1 MHz intervals until the frequency of the received RF activation signal is identified.
After retrieving the first or next available frequency in the frequency table, microcontroller 57 tunes antenna 59 to a resonant frequency matching the retrieved frequency (block 222). Additionally, microcontroller 57 clears a mode save (MODSV) register. Next, microcontroller 57 sets the frequency of the signal generated by VCO 73 to a reference frequency 3 MHz below the retrieved frequency by providing the appropriate R and N values to divide-by-R register 92 and divide-by-N register 93 and instructs serial port and control logic circuit 75 to output a receive signal RX to enable receive buffer 81, mixer 79, receive amplifier 83, and integrator 84.
Next, microcontroller 57 outputs a signal to cause LED 48 to blink in order to inform the person who depressed one of switches 44, 46, and 47 that they should activate the remote garage door transmitter 65 to which trainable transceiver 43 is to be trained. Subsequently, antenna 59 receives the RF activation signal transmitted by remote transmitter 65 and provides the received signal to mixer 79 where the received RF activation signal is mixed with the signal output from VCO 73. If the frequency of the signal output by VCO 73 is 3 MHz above or below the frequency of the received RF activation signal, microcontroller 57 will detect any ASK data contained in the received RF activation signal and will call a "VERIFY" subroutine to verify the presence of a valid data code signal (block 223) and identify the data code as "fast" or "slow" data.
Fast data is detected when the data has more than five rising edges in a 850 .mu.sec interval. Slow data is detected when the data has five or less rising edges in a 850 .mu.sec interval, but more than five rising edges detected in a 70 msec interval. Fast data includes two general types of data--GENIE data, which is transmitted from GENIE brand transmitters, and non-GENIE (single tone) data. The distinction between GENIE and non-GENIE data is made in an ENCODE subroutine described below. GENIE data differs from the data transmitted by other brands of remote garage door transmitters in that the GENIE data is frequency shift-keyed data having pulse repetition rates that shift between 10 and 20 kHz. GENIE data is typically transmitted at a carrier frequency that falls between 290 and 320 MHz at 5 MHz intervals. As will be apparent from the description below, the classification of the data as either fast, slow, GENIE, or single tone affects the manner by which microcontroller 57 subsequently checks, stores, and encodes the data.
The VERIFY subroutine is shown in FIG. 10 and begins at block 224 at which point microcontroller 57 begins a 850 microsecond timer. In blocks 226 and 228, microcontroller 57 counts the number of rising edges in the ASK data within the 850 .mu.sec interval measured by the timer. In block 230, microcontroller 57 determines whether the number of detected rising edges is greater than five. If the number of rising edges is greater than five, microcontroller 57 sets a data acknowledge (DACK) flag to "1" indicating that data has been verified and sets a mode bit to "1" indicating that the data is fast (block 232) and returns to block 234 (FIG. 9A) where microcontroller 57 updates the MODSV register to store the value of the mode bit.
If the microcontroller program determines in block 230 that the number of detected rising edges is not greater than five, the program advances to block 236 where it begins a 70 msec timer. In blocks 238 and 240, the program counts the number of rising edges detected during the 70 msec interval. If the number of rising edges is greater than five (block 242), the program sets the DACK flag to "1" and the mode bit to "0" (block 244) indicating that the data is slow and returns to the block following that block which last called the VERIFY subroutine. If microcontroller 57 determines that the number of rising edges detected during the 70 msec interval is not greater than five, the program sets the DACK flag to "0" indicating the absence of verified ASK data, sets the mode bit to "0", and returns to the block following that block which last called the VERIFY subroutine, as indicated in block 246.
Referring back to FIG. 9A, after returning from the VERIFY subroutine and updating the MODSV register, the program looks at the DACK flag to determine whether verified ASK data is present (block 248). If data is not present, the program advances to block 250 where the X counter is incremented. Then, the program determines whether the X counter is equal to 1 (block 252). Upon determining that X is equal to 1, microcontroller 57 decreases the frequency of VCO 73 by 1 MHz (block 254) and then repeats the steps set forth in blocks 220-234. Then in block 248, microcontroller 57 again determines whether data was detected as being present. By looking for data at a frequency 4 MHz below a frequency stored in the frequency table, microcontroller 57 can check whether the received activation signal is transmitted at a slightly lower frequency than expected due to production variances that may be present in the remote transmitter.
If data is again not present, the program increases the X counter (block 250) and checks whether the value of X is equal to 1 (block 252). If X is not equal to 1, the program advances to block 256 where it determines whether any data had been previously detected by looking at a DATPREV flag. As discussed below, the DATPREV flag is set only after the received code signal has been rigorously tested. If data had been previously detected, microcontroller 57 causes LED 48 to rapidly blink (block 258) indicating a successful training sequence. On the other hand, if the microcontroller program determines that data had not been previously detected, it returns to block 218 to retrieve the next frequency in the frequency table and to clear the X register.
Microcontroller 57 repeats the sequence of steps set forth above and identified in blocks 218-256 until microcontroller 57 detects the presence of data in block 248. When data is present, the program advances to block 260 (FIG. 9B) where it saves the value of X, which will have a value of "0" if data was detected when the frequency of VCO 73 was 3 MHz below the last frequency retrieved from the frequency table, or a value of "1" if the frequency of VCO 73 is 4 MHz below the last retrieved frequency from the frequency table. Next, the microcontroller program adds the intermediate frequency (IF) of bandpass filter 82, which is preferably 3 MHz, to the frequency of the signal previously output from VCO 73. Additionally, microcontroller 57 tunes the antenna to an appropriate frequency for this increased VCO frequency (block 262).
Next, in block 264, the program checks to determine whether data is present by calling the VERIFY subroutine. If the frequency of VCO 73 was 3 MHz below the frequency of the received RF activation signal when microcontroller 57 verified the presence of data in block 248 (FIG. 9A), the detected data will typically disappear when a frequency of VCO 73 is increased by 3 MHz to be the same frequency as the RF activation signal. If, however, microcontroller 57 determines in block 266 that data is present when the frequency of VCO 73 is increased by 3 MHz, the microcontroller program checks the value of X in block 268 to determine whether the frequency of VCO 73 was previously set to 4 MHz below the frequency that was last retrieved from the frequency table. If the VCO frequency is 4 MHz below the last retrieved frequency from the frequency table, microcontroller 57 increments the VCO frequency by 1 MHz, retunes antenna 59 (block 270), and again attempts to verify the presence of data by returning to block 264. If data is again detected, the program advances to block 272 where the mode bit of the original data that was verified is restored to its initial value, which was stored in the MODSV register. Then, the microcontroller program puts the detected data through a more rigorous test by calling an "ENCODE" subroutine in block 274.
In the ENCODE subroutine shown in FIGS. 11A and 11B, microcontroller 57 first clears its RAM in block 276 and determines whether the mode bit is equal to 1 in block 278. If the mode bit is equal to 1, microcontroller 57 enables interrupts (block 280) such that it may identify each period in the data string as either 10 kHz or 20 kHz (block 282). Next, microcontroller 57 determines whether it has received twelve consecutive 10 kHz periods (block 284) in order to determine whether the data is frequency-shift keyed corresponding to an activation signal transmitted by a GENIE brand transmitter. If twelve consecutive 10 kHz periods have not been received, the program increments an error counter (block 286), and checks whether the error counter has reached too high a value (block 288). Provided that the error counter has not reached too high a value, microcontroller 57 continues to identify each period as either 10 kHz or 20 kHz (block 282) and to determine whether twelve consecutive 10 kHz periods have been received (block 284).
If microcontroller 57 receives twelve consecutive 10 kHz periods and fills the RAM with the received data corresponding to the number of 10 kHz and 20 kHz periods (block 290), the program sets the success flag (block 292) and returns to the block following that in which the ENCODE subroutine was last called.
If, however, in block 288, the program 57 determines that the error counter has reached too high a value, it determines that the received data is "single tone" data and sets a flag indicating that the data is single tone (block 294). In block 296, microcontroller 57 then determines whether the data has long periods of dead time. If the data has long periods of dead time, microcontroller 57 identifies the data as single tone data in word format, sets a word format flag, and measures and stores the length of the dead time (block 298). After determining that the data does not have long periods of dead time, or after identifying the data as single tone data in word format, microcontroller 57 stores the data string in the RAM and measures the periods of 250 cycles of the received data in block 300. Next, microcontroller 57 categorizes the results into two possible frequencies, saving the length of the period and the number of matches to each (block 302). If microcontroller 57 determines in block 304 that more than two hundred matches have been found for one of the two frequencies, it then determines in block 306 whether the data could be considered "dirty" GENIE data by determining whether either one of the two frequencies used to categorize the cycles are at or near 10 or 20 kHz. If the data could be dirty GENIE data, or if more than two hundred matches are not found in block 304, the microcontroller program clears the success flag in block 308 and returns to the block following that block in which the ENCODE subroutine was last called.
If, in block 306, microcontroller 57 determines that the data could not be dirty GENIE data, microcontroller 57 saves the period at which more than 200 matches were found (block 310), sets the success flag (block 312), and the program returns to the block following that block in which the ENCODE subroutine was last called.
If, in block 278 of the ENCODE subroutine of FIG. 11A, microcontroller 57 determines that the mode bit is not equal to one indicating that the received data is slow, microcontroller 57 sets up to sample the received data at 68 .mu.sec in block 314 (FIG. 11B). Then, in block 316, microcontroller 57 looks for a start condition in the received data which is present when seventy consecutive samples are found at a low logic level. If the start condition is not found (block 318), microcontroller 57 identifies the data as "constant pulse data" in block 320. After the data is identified as "constant pulse data" or after a start condition is detected in block 318, microcontroller 57 then determines whether the data was lost in block 322 by determining whether the number of consecutive samples at a low logic level exceed a predetermined number. If microcontroller 57 determines that the data was lost in block 322, it clears the success flag in block 324 and the program returns to the block following that block which called the ENCODE subroutine. On the other hand, if microcontroller 57 determines that the data was not lost, it stores the data as the number of consecutive samples at either a high or low logic level (block 326), sets the success flag (block 328), and the program returns to the block following that block which called the ENCODE subroutine.
Returning to FIG. 9B, if the data that was verified at the last retrieved frequency in the frequency table and also at a frequency 3 MHz below the last retrieved frequency is successfully encoded (block 330), the microcontroller program checks the X value to determine whether the frequency of the VCO 73 was last set to a value 4 MHz below the last retrieved frequency from the frequency table (block 332). If the VCO was previously set at a frequency 4 MHz below the last retrieved frequency, microcontroller 57 increments the VCO frequency by 1 MHz, retunes antenna 59 (block 334), and the program returns to block 274 to try to encode the data. If this data is then successfully encoded, the program advances to block 336 where a noise counter NOISCNT is incremented.
Next in block 338, microcontroller 57 checks the value of NOISCNT to determine whether this value is too high indicating that trainable transceiver 43 is receiving noise at those frequencies at which data was verified. If the NOISCNT value is too high, microcontroller 57 determines whether the frequency last retrieved from the frequency table was a Canadian frequency (i.e., a frequency associated with an activation signal of short duration) (block 340).
If the value of NOISCNT is not too high (block 338), or if the value of NOISCNT is too high and the frequency last retrieved from the frequency table is not a Canadian frequency, the program goes to block 341 (FIG. 9A) where it restores the frequency of VCO 73 and the value of X to the values they had prior to transferring to block 260 in FIG. 9B. Then the program increments the value of X in block 250 and determines in block 252 whether the value of X is equal to 1. If the value of X is not equal to 1, the program advances to block 256 where it determines whether data was previously detected. If data was previously detected, microcontroller 57 then outputs a signal to cause LED 48 to rapidly blink, thereby indicating a successful train (block 258). If, however, X is equal to 1 (block 252), microcontroller 57 decreases the frequency of the VCO by 1 MHz (block 254), and looks for data at that frequency by repeating the steps set forth in blocks 220-248.
Referring back to FIG. 9B, if the program determines in blocks 338 and 340 that NOISCNT is too high and the frequency last retrieved from the frequency table is a Canadian frequency, the program sets the pointers in the frequency table to point to the first frequency following the Canadian frequencies (block 342) and advances to block 218 (FIG. 9A) in order to attempt to detect data at the remaining frequencies stored in the frequency table.
As stated above, when a valid data code is present when the frequency of VCO 73 is set 3 MHz below the frequency of the RF activation signal, the data should disappear when the frequency of VCO 73 is increased by 3 MHz to coincide with the frequency of the received RF activation signal. Moreover, if the data, which is detected when the frequency of VCO 73 is increased to be the same as the frequency of the received RF activation signal, cannot be successfully encoded (block 330), a valid data code may be present. Thus, if data was not detected in block 266, or if detected data was not successfully encoded in block 330, the program advances to block 344 (FIG. 9C) where it adds the intermediate frequency of 3 MHz to the VCO frequency and retunes antenna 59.
Next, the program checks to determine whether verifiable data has reappeared by calling the VERIFY subroutine in block 346 (FIG. 9C). If the program determines that data is present in block 348, the program then tests (block 350) to determine whether the detected data is fast by examining whether the mode bit is equal to 1 or 0. If the data is fast (i.e., MODE=1), the program executed by microcontroller 57 attempts to encode this fast data in block 352 by calling the ENCODE subroutine of FIG. 11A. If the fast data is not successfully encoded (block 354), or if the program determines that data is not present in block 348, microcontroller 57 increments the VCO frequency by 1 MHz, retunes antenna 59 (block 356), and reattempts to verify the presence of data by calling the VERIFY subroutine (block 358) of FIG. 10.
If data is present (block 360), microcontroller 57 determines whether the data is fast in block 362. If the data is fast, microcontroller 57 attempts to encode this fast data by calling the ENCODE subroutine as indicated in block 364. If the fast data is not successfully encoded (block 366), or if microcontroller 57 does not detect data in block 360, microcontroller 57 decrements the VCO frequency by 2 MHz, retunes antenna 59 (block 368), and checks for the presence of data in block 370 by calling the VERIFY subroutine.
If the program then determines that data is present in block 372 (FIG. 9D), the program determines whether the detected data is fast data in block 374. If the detected data is fast data, the program attempts to encode this fast data in block 376 by calling the ENCODE subroutine. If this fast data is not successfully encoded (block 378), or if the program determines that data is not present in block 372, the program advances to block 336 (FIG. 9B) and performs the process indicated in blocks 336-342 as indicated above.
In the event the program detects data which is not fast in blocks 350, 362 (FIG. 9C), or in block 374 (FIG. 9D), the program advances to block 380 in FIG. 9E. Similarly, if the program successfully encodes detected fast data in blocks 354, 366 (FIG. 9C), or block 378 (FIG. 9D), the program advances to block 380 in FIG. 9E.
Having advanced to block 380 in FIG. 9E, the mode bit is restored to the value saved in the MODSV register and the frequency of VCO 73 is restored to the frequency at which data was first detected. Microcontroller 57 then determines whether the identified frequency of the received activation signal is one known to be used with rolling, real-time, or other variable codes (block 381). Alternatively or additionally, microcontroller 57 may check other characteristics of the received activation signal, such as the number of bits in the code to determine whether the code is a variable code. If the code is potentially a variable code, microcontroller 57 calls a rolling code ID (RCID) subroutine 382, an example of which is described now with reference to FIG. 13.
In the rolling code ID subroutine 382, microcontroller 57 first determines whether the received code is dynamically changing (i.e., changing within on actuation of the transmit button) (block 500). If the code is not dynamically changing, microcontroller 57 stores the identified code in a first memory location MEM1 (block 501) and prompts the user to re-actuate the transmit button on remote transmitter 65 (block 502). Then, using the same frequency to demodulate the received re-transmitted activation signal, microcontroller 57 receives and stores the code included in this signal in another memory location MEM2 (block 506). Microcontroller 57 then compares the codes stored in the two memory locations (block 508) and determines whether the codes are different (block 510). If the codes are not different, microcontroller 57 determines that remote transmitter 65 does not utilize a variable code and the program returns to block 383 (FIG. 9E). If the two codes are different or if the received code is changing dynamically, microcontroller 57 examines the characteristics of the received activation signal and compares such information with stored transmitter identification data to determine the make and model of remote transmitter 65. Such characteristics may include the pulse width, pulse repetition rate, number of codes bits, and/or the identified carrier frequency. Based upon an identification of the make and model of remote transmitter 65, microcontroller 57 identifies a cryptographic algorithm, which is previously stored in memory, corresponding to the cryptographic algorithm used by the identified remote transmitter and receiver of the same make and model (block 514). If the cryptographic algorithm is not previously stored in the microcontroller's memory, it may be downloaded through input terminal 62a. Additionally, if microcontroller 57 cannot identify the manufacturer of the remote transmitter based upon the characteristics of the received activation signal, microcontroller 57 may prompt the user to input an identification code or name identifying the make and model of the remote transmitter. Such information may be input by pushing various combinations of switches 44, 46, and 47 or by using a user interface, such as that disclosed in above-mentioned U.S. patent application Ser. No. 08/293,487, via input terminal 62a.
After the cryptographic algorithm is identified or otherwise provided, microcontroller 57 prompts the user to perform a "special sequence" to identify the serial number associated with either the last transmitted code or the code to be transmitted next (block 516). This special sequence is that which is performed to re-synchronize the transmitter and receiver according to the methodology used by the particular manufacturer. In some cases this may involve any or one or combination of the following: pressing the transmit button of remote transmitter 65 twice in rapid succession, holding the transmit button down for a predetermined time period, pressing a second transmit button, pressing a combination of buttons, entering a code on a keypad of remote transmitter 65, etc. Such a special sequence may also involve operating a re-synchronization or reset switch on the receiver of garage door opening mechanism 66 causing the receiver to accept and re-synchronize on the next code it receives.
After identifying the cryptographic algorithm and the serial number of the next code to be transmitted, microcontroller 57 has the information necessary to subsequently generate the proper sequence of codes for opening the garage door provided the cryptographic algorithm does not utilize a cryptographic key. If the algorithm does require such a key, microcontroller 57 must either learn or receive the cryptographic key used by the remote transmitter and associated receiver, or randomly generate a cryptographic key that may be transmitted in a special signal or otherwise communicated to the receiver. Thus, microcontroller 57 will determine whether there is an original transmitter (OT) sequence to download the cryptographic key based upon the known methodology employed by the identified manufacturer (block 518).
If an original transmitter sequence is available to download the cryptographic key, microcontroller 57 will execute a prestored algorithm to perform the sequence (block 520). The sequence may involve prompting the user to perform certain tasks such as pressing a particular transmit button on remote transmitter 65, or any similar technique such as those described above with respect to the special sequence for re-synchronization. The performance of the original transmitter sequence will result in the cryptographic key being downloaded into the non-volatile memory of microcontroller 57 (block 522).
Microcontroller 57 may then decipher the serial number for synchronization purposes (if necessary) using the cryptographic algorithm and the cryptographic key (block 524). Then microcontroller 57 will cause LED 48 to rapidly blink indicating that the signal has been successfully trained (block 526).
If there is no original transmitter sequence for downloading the cryptographic key, microcontroller 57 will assume the receiver of garage door opening mechanism 66 may be reset by pressing a button thereon or performing some other sequence, to receive and utilize a new cryptographic key. Thus, microcontroller 57 will randomly generate a cryptographic key (block 528) and will synchronize the receiver by transmitting the key to the receiver using the appropriate protocol for the identified make and model receiver to download the new key (block 530). When the receiver is synchronized, microcontroller 57 causes LED 48 to rapidly blink indicating a successful training sequence (block 526).
If more than one transmitter is used to open the garage door, microcontroller 57 can identify the portion of the transmitted code including the transmitter ID tag by regenerating the received code using the cryptographic algorithm and comparing the regenerated code with the received code to determine the part of the code that represents a message header including the transmitter ID tag. The identified ID tag may then be stored along with any other data including in a fixed message header for subsequent re-transmission along with the variable code.
Referring back to FIG. 9E, if the frequency is not one known to be used for variable codes, the noise counter NOISCNT is cleared (block 383) and the VERIFY subroutine is called in block 384. Then, if verifiable data is not present (block 386), microcontroller 57 sets a five second timer and begins slowly double blinking LED 48 in a distinctive manner in order to prompt operator to again depress the activation switch on remote transmitter 65 (block 388). Although not usually necessary, by prompting the operator to cause the remote transmitter to retransmit its activation signal, microcontroller 57 increases the likelihood that trainable transceiver 43 can successfully learn a short duration activation signal.
Next, the program repeatedly calls the VERIFY subroutine (block 390) until verifiable data is detected (block 392), or a predetermined time interval, such as five seconds, has expired (block 394). If verifiable data is detected in block 386 or block 392, or if time has expired in block 394, the program calls the ENCODE subroutine (block 396). Then, if the data is not successfully encoded (block 398), the program increments the noise counter NOISCNT (block 400) and checks whether NOISCNT is equal to 4 (block 402). If NOISCNT is not equal to 4, the program returns to block 384 to again attempt to verify and encode the received data code. If NOISCNT is equal to 4 (block 402), the program advances to block 341 in FIG. 9A where the VCO frequency and the X counter is restored and the process advances to block 250 as previously described above.
If, in block 398, it is determined that the data code was successfully encoded, the program checks whether the data was previously identified as single tone data in block 404. If the data is single tone data, the program then determines whether a stubborn (STUBRN) bit had been previously set (block 406). Initially, the STUBRN bit is not set. However, if the STUBRN bit is subsequently set in block 494 (FIG. 9G) due to an inability to previously successfully train single tone data, and the process returns back to block 406, the program increments noise counter NOISCNT in block 400 and advances through the process in the manner previously discussed above. If, in block 404, microcontroller 57 determines that the detected data is not single tone data, microcontroller 57 attempts to condense the encoded data by calling a CONDENSE subroutine in block 408. The CONDENSE subroutine is employed to attempt to condense the data stored in memory during the last execution of the ENCODE subroutine such that the stored code signal, which may repeat a data sequence numerous times, does not consume more memory than necessary. The CONDENSE subroutine is now described with reference to FIG. 12.
Initially, in block 410, the program determines whether the mode bit is equal to 1. If the mode bit is equal to 1, the program determines whether any data is present with three or less periods (i.e., whether the encoded data contains a data sequence that is repeated three or fewer times within the string of data that was encoded and stored in microcontroller 57). If the data has three or less periods, the program indicates in block 414 that the attempt to condense the data has failed and returns to block 446 (FIG. 9E).
If, on the other hand, no data is present with three or less periods, the program then determines whether the encoded and stored data has any 10 kHz data with more that 30 periods (block 416). If there is 10 kHz data with more than 30 periods, the program indicates that the attempt to condense the data has failed (block 414) and returns to the process in FIG. 9E (block 446). If there is no 10 kHz data present with more than 30 periods (block 416), the program sets the start pointer of the condensed data code to the first data location of the encoded and stored data (block 418). Next, the program sets the end pointer for the stored condensed data equal to the last 10 kHz data having more than 12 periods (block 420) and indicates that the attempt to condense the data was successful (block 422) before returning to block 446 in FIG. 9E. In this manner, the stored encoded data may be condensed to a shorter form that may be repeatedly read from memory during a transmit mode.
If, in block 410, the program determines that the mode bit is not equal to 1, it then determines whether the stored encoded data includes a long low period (block 424). If the stored data does not include a long low period, it is determined in block 426 that the data is continuous and, in block 428, the program determines that the entire data bank should be used to store the encoded data. If, in block 424, it is determined that the data does include a long low period, the start pointer for the condensed data is set equal to the first location of the stored encoded data (block 430) and the end pointer of the condensed data is set equal to the last location of the long low period within the stored encoded data (block 432).
Subsequently, the program looks at the stored condensed data to determine whether the data includes any continuous logic high states of 120 samples or more (block 434). If any such continuous high logic periods are found, the program indicates that the attempt to condense the data has failed in block 436 and returns to block 446 in FIG. 9E. If there are not any consecutive high periods of 120 or more samples, then the stored condensed data is examined to determine whether there are any occurrences of a logic high or low state that does not exist for two consecutive samples (block 440). If such an occurrence is identified, it is indicated in block 436 that the attempt to condense the data has failed and the program advances to block 446.
If there are no such occurrences in block 440, it is determined whether the stored condensed data string from start to end is less than ten samples (block 442). If the data string is less than ten samples long, it is indicated that the attempt to condense the data has failed in block 436. On the other hand, if the stored condensed data consists of 10 or more samples, it is indicated that the attempt to condense the data was successful in block 444 and the program advances to block 446 in FIG. 9E.
In block 446 of FIG. 9E, it is determined whether the attempt to condense the encoded data was successful. If the attempt was not successful, microcontroller 57 increments the noise counter NOISCNT in block 400 and the program proceeds in the manner discussed above. If the encoded data was successfully condensed, the program determines whether the data was previously found to be constant pulse data (block 448). If the data is not constant pulse data, the program again attempts to encode the data by calling the ENCODE subroutine of FIGS. 11A-B in block 450. If the data is constant pulse data, or if the data is successfully encoded in block 450 as indicated by test block 452, the program advances to block 454 in FIG. 9F (block 452). Otherwise, the program advances to block 400 where it increments the noise counter NOISCNT and proceeds as described above.
In block 454 (FIG. 9F), the program determines whether the data is GENIE data by looking at the mode bit and the single tone bit. If the mode bit is equal to 1 and the single tone flag is not set, the program advances to block 456 where microcontroller 57 sorts the identified carrier frequency of the received activation signal into one of several known GENIE operating frequencies falling within the range of 290-320 MHz at 5 MHz intervals. Thus, for example, if the identified carrier frequency of the received activation signal is between 301 and 304 MHz, microcontroller 57 determines that the carrier frequency to store and subsequently transmit should be the closer of 300 and 305 MHz. Also in block 456, the program sets the DATPREV flag to indicate that data has been detected. Then, the program advances to block 458 and microcontroller 57 stores the new data prior to returning to block 218 in FIG. 9A.
If, in block 454, the program determines that the mode bit is not equal to 1, the program then determines whether the value of X is equal to "0" in order to determine whether data was first detected when the frequency of VCO 73 was set 3 MHz below the frequency in the frequency table (block 460). If the value of X is equal to "0", the program looks to the next value in the frequency table to determine whether this value is 1 MHz away from the previous value (block 462). If the next frequency in the frequency table is 1 MHz away, microcontroller 57 stores the new data (block 458) and the program returns to block 218 (FIG. 9A) and proceeds as described previously. If the next frequency in the frequency table is not 1 MHz away from the previous frequency, microcontroller 57 saves the data and outputs a signal causing LED 48 to rapidly blink, thus indicating a successful training sequence (block 464).
If, in block 460, the program determines that X is not equal to "0", it checks whether the DATPREV flag is equal to 1 (block 466). If the DATPREV flag is not equal to 1, microcontroller 57 saves the data and outputs a signal causing LED 48 to rapidly blink (block 464). If DATPREV flag is equal to 1, the program determines whether the previous data was trained at 3 MHz below a frequency stored in the frequency table (block 468). If the previous data was trained at 3 MHz below a frequency stored in the frequency table, microcontroller 57 reverts back to the data obtained when the VCO frequency was 3 MHz below a frequency in the frequency table and causes LED 48 to rapidly blink acknowledging a successful training sequence (block 470). If the previous data was not trained when the frequency of VCO 73 was 3 MHz below a frequency in the frequency table (block 468), microcontroller 57 saves the data and causes LED 48 to rapidly blink (block 464) indicating a successful training sequence.
Referring back to FIG. 9E, if microcontroller 57 determines that the retrieved data code is single tone in block 404 and determines that the STUBRN bit is not set in block 406, the program advances to block 472 in FIG. 9G. In block 472, microcontroller 57 determines whether the DATPREV flag is set. If the DATPREV flag is set, microcontroller 57 causes LED 48 to rapidly blink indicating a successful training sequence (block 474). If, on the other hand, microcontroller 57 determines that the DATPREV flag is not set, microcontroller 57 determines whether it is operating in the Canadian fast mode by determining whether the last frequency read from the frequency table is a Canadian frequency (block 476). If microcontroller 57 is operating in a Canadian fast mode, the program advances to block 308 in FIG. 9A and proceeds as previously discussed. If microcontroller 57 is not operating in the Canadian fast mode, it adds the intermediate frequency of 3 MHz to the frequency of VCO 73 (block 478).
Next, microcontroller 57 stores the value of R and stores the value of N required for the increased VCO frequency in the NVM of microcontroller 57 (block 480). Next, microcontroller 57 decreases the frequency of VCO 73 by 2 MHz (block 482) and saves this frequency in the variable DATCHK (block 484). Then, the program calls the ENCODE subroutine of FIGS. 11A-B (block 486) to attempt to encode data at this new VCO frequency. If this data is not successfully encoded (block 488), the program sets the DATPREV flag (block 490) and returns to block 218 of FIG. 9A. By returning to block 218, the program may check whether data may be verified at frequencies 3 or 4 MHz below the next frequency in the frequency table. Provided verified data is not found at these frequencies, a successful train may be indicated in block 258 because the program will determine that the DATPREV flag had been set in block 256.
If, in block 488, the program determines that the attempt to encode data is successful, it determines whether the encoded data is single tone data in block 492. If the data is not single tone data, microcontroller 57 clears the noise counter NOISCNT and sets the STUBRN bit (block 494) and advances to block 480 in FIG. 9E. If the successfully encoded data is single tone data, microcontroller 57 checks the frequency of the data to determine whether it is greater than 18 kHz (block 496). Then, if the data has a frequency greater than 18 kHz, microcontroller 57 checks whether any previous data had a frequency less than 15 kHz (block 498). If any previous data did not have a frequency less than 15 kHz, or if the frequency of the successfully encoded single tone data is not greater than 18 kHz, the microcontroller program returns to block 476 and proceeds as previously discussed. If any previous data did have a frequency less than 15 kHz, the program sets the DATPREV flag (block 500) and returns to block 218 of FIG. 9A and proceeds as previously described.
The above process is continued until a successful training sequence is acknowledged or until microcontroller 57 has looked for data at all frequencies at 1 MHz intervals between the 200 and 400 MHz range, in which remote transmitters typically operate.
Although the present invention has been described as including specific elements and as operating in a specific manner in accordance with a preferred embodiment, certain aspects of the present invention may be practiced without requiring the particulars of another feature of the present invention. For example, the trainable transceiver of the present invention need not include a dynamically tunable antenna or a variable gain amplifier and need not perform the procedures for training to short duration activation signals. Similarly, the procedures for training to variable activation signals need not be practiced with the particular structural implementation of the preferred embodiment disclosed above. For example, the variable activation signal training procedures could be implemented in a trainable transceiver such as that disclosed in U.S. Pat. No. 5,442,340 or that disclosed in U.S. Pat. No. 5,475,366.
Additionally, methods other than those disclosed above may be used to provide any required data to the microcontroller for training to a variable code activation signal. For example, data, such as the cryptographic key, may be transmitted to the microcontroller of the trainable transceiver using paging signals. A system for receiving paging signals for controlling vehicle accessories is disclosed in U.S. Pat. No. 5,479,157 entitled REMOTE VEHICLE PROGRAMMING SYSTEM, the disclosure of which is incorporated by reference herein. Another approach would be for a manufacturer to provide a compact disc (CD-ROM) with systems utilizing a variable code that would include the cryptographic algorithm and key for downloading to the trainable transceiver microcontroller from the vehicle's CD player. A system utilizing a CD in a vehicle's CD player for controlling vehicle accessories is disclosed in U.S. Pat. No. 5,525,977 issued on Jun. 11, 1996, and entitled PROMPTING SYSTEM FOR VEHICLE PERSONALIZATION, the disclosure of which is incorporated by reference herein.
If a remote transmitter that transmits a variable code is adapted to also transmit a re-synchronization signal to the receiver when the transmitter and receiver become out of sync, the trainable transceiver of the present invention may be trained to learn and re-transmit such a re-synchronization signal. This could be readily accomplished by training one of the other channels of the transceiver using the procedure described above for training to the activation signal.
Although the present invention has been described as including specific elements and as operating in a specific manner in accordance with a preferred embodiment, certain aspects of the present invention may be practiced without requiring the particulars of another feature of the present invention.
It will be understood by those who practice the invention and by those skilled in the art, that various modifications and improvements may be made to the invention without departing from the spirit or scope of this invention which is to be determined by the claims and by the breadth of their interpretation allowed by law.

Claims

1. A trainable transmitter for learning the signal characteristics of a received RF signal and for subsequently transmitting a modulated RF signal having the learned characteristics, said trainable transmitter comprising:
an antenna for receiving an RF signal from a remote control transmitter used to remotely actuate a device, the RF signal having signal characteristics including a data code and an RF carrier frequency that is initially an unknown frequency within a predefined frequency band between a first frequency and a second frequency;
a tunable RF circuit coupled to said antenna for receiving RF signals received by said antenna, said RF circuit having a data output terminal and a frequency control terminal for receiving frequency control signals, wherein said RF circuit is selectively tuned to a frequency corresponding to a frequency control signal applied to said frequency control terminal, said RF circuit providing any data code present in a received RF signal at said data output terminal whenever the RF carrier frequency of the received RF signal corresponds to the frequency at which said RF circuit is tuned; and
a control circuit coupled to said frequency control terminal and to said data output terminal of said RF circuit, said control circuit being operative in a training mode and in an operating mode, when in the training mode, said control circuit initiates a training sequence by applying a first frequency control signal to said frequency control terminal to tune said RF circuit to said first frequency and immediately thereafter applying a second frequency control signal to said frequency control terminal to tune said RF circuit to said second frequency in order to create a rapid transition from said first frequency to said second frequency, wherein, during the rapid transition from said first frequency to said second frequency, said RF circuit supplies a detection signal at said data output terminal representing the presence of a received RF signal having an RF carrier frequency within said predefined frequency range, and, in response to said detection signal, said control circuit continues said training sequence by identifying the RF carrier frequency and code of the received RF signal.
2. The trainable transmitter as defined in claim 1 wherein said transition is about 0.005 seconds.
3. The trainable transmitter as defined in claim 1 and further including an indicator circuit coupled to said control circuit for providing a user with an indication that an RF signal has been detected within said predefined range in response to an activation signal received from said control circuit.
4. The trainable transmitter as defined in claim 3, wherein said indicator circuit includes an indicator light that is illuminated in response to said activation signal.
5. The trainable transmitter as defined in claim 1, wherein said control circuit aborts said training sequence if a detection signal is not received from said RF circuit within a predetermined time period after the training sequence is initiated.
6. The trainable transmitter as defined in claim 5, wherein said control circuit repeatedly and alternatingly supplies said first frequency control signal and said second frequency control signal to said frequency control terminal until a detection signal is received or said predetermined time period has lapsed.
7. The trainable transmitter as defined in claim 1 wherein, in said training mode, said control circuit further stores data representing the identified RF carrier frequency and data code and, when in an operating mode, said control circuit reads said data, generates and supplies a frequency control signal representing the identified carrier frequency of the received activation signal to said frequency control terminal of said RF circuit, and supplies a code signal representing the learned data code to a data input terminal of said RF circuit, and wherein said RF circuit responds by generating and transmitting a modulated RF signal having the learned frequency and code to a remotely actuated device.
8. The trainable transmitter as defined in claim 1, wherein said RF circuit includes:
a signal generator having an input terminal serving as said frequency control terminal, said signal generator generates a signal having a carrier frequency corresponding to a frequency control signal applied to said frequency control terminal;
a mixer coupled to said antenna and to said signal generator for mixing the received RF signal with a signal supplied by said signal generator;
a narrow bandpass filter coupled to said mixer for receiving all signal components output from said mixer as a result of mixing the received RF signal with the signal supplied from said signal generator, said bandpass filter filters all but a signal component output from said mixer having predefined carrier frequency, wherein the output of said mixer will have a signal component having the predefined carrier frequency when the frequency of said signal generated by said signal generator has a predefined relationship with the received RF signal; and
an integrator coupled to said bandpass filter for receiving and demodulating any output signal component from said bandpass filter to provide either a detection signal or a detected data code to said control circuit at said data output terminal of said RF circuit.
9. The trainable transmitter as defined in claim 8, wherein said control circuit repeatedly and alternatingly applies said first frequency control signal and said second frequency control signal to said frequency control terminal of said signal generator causing said signal generator to supply a signal that continuously varies between said first frequency and said second frequency thereby causing a detection signal to be output from said data output terminal if an RF signal is received having a carrier frequency within said predefined frequency range.
10. The trainable transmitter as defined in claim 9, wherein said control circuit continues to apply said first and second frequency control signals until said control circuit receives a detection signal from said integrator or until a predetermined time period has expired.
11. The trainable transmitter as defined in claim 1, wherein said antenna is a dynamically tunable antenna having a control input coupled to said control circuit, and having a tunable element for adjusting the resonant frequency of said antenna in response to antenna control data applied to said control input by said control circuit.
12. The trainable transmitter as defined in claim 11 wherein, when said control circuit adjusts the tuning of said RF circuit to jump from said first frequency to said second frequency in about 5 milliseconds and wherein said control circuit provides antenna control data to said control input of said dynamically tunable antenna to jump the resonant frequency at which said dynamically tunable antenna is tuned from said first frequency to said second frequency.
13. The trainable transmitter as defined in claim 11, wherein said control circuit includes a microcontroller and a digital-to-analog converter coupled between said microcontroller and said control input of said dynamically tunable antenna.
14. The trainable transmitter as defined in claim 1, wherein said first frequency is lower than said second frequency.
15. A trainable transceiver for learning the signal characteristics of a received RF signal and for subsequently transmitting a modulated RF signal having the learned characteristics, said trainable transmitter comprising:
a dynamically tunable antenna having a control input for receiving antenna control signals and having a tunable element for adjusting the resonant frequency of said antenna in response to the antenna control signals applied to said control input, said antenna is adapted to receive an RF signal from a remote control transmitter used to remotely actuate a device, the RF signal having signal characteristics including a data code and an RF carrier frequency that is initially an unknown frequency within a predefined range between a first frequency and a second frequency;
a tunable RF circuit coupled to said antenna for receiving RF signals received by said antenna, said RF circuit having a data output terminal and a frequency control terminal for receiving frequency control signals, wherein said RF circuit is selectively tuned to a frequency corresponding to a frequency control signal applied to said frequency control terminal, said RF circuit providing any data code present in a received RF signal at said data output terminal whenever the RF carrier frequency of the received RF signal corresponds to the frequency at which said RF circuit is tuned; and
a control circuit coupled to said control input of said antenna, and to said frequency control terminal and said data output terminal of said RF circuit, said control circuit being operative in a training mode and in an operating mode, when in the training mode, said control circuit initiates a training sequence by applying a first frequency control signal to said frequency control terminal and a first antenna control signal to said control input to tune said RF circuit and said antenna to said first frequency and immediately thereafter applying a second frequency control signal to said frequency control terminal and a second antenna control signal to said control input to tune said RF circuit and said antenna to said second frequency and to cause said tunable RF circuit to jump from being tuned to said first frequency to being tuned to said second frequency,
wherein, during the jump from said first frequency to said second frequency, said RF circuit supplies a detection signal at said data output terminal representing the presence of a received RF signal having an RF carrier frequency within said predefined frequency range, and, in response to said detection signal, said control circuit continues said training sequence by identifying the RF carrier frequency and code of the received RF signal.
16. The trainable transceiver as defined in claim 15 and further including an indicator light coupled to said control circuit that is illuminated to provide a user with an indication that an RF signal has been detected within said predefined range in response to an activation signal received from said control circuit.
17. The trainable transceiver as defined in claim 15, wherein said control circuit aborts said training sequence if a detection signal is not received from said RF circuit within a predetermined time period after the training sequence is initiated.
18. The trainable transceiver as defined in claim 17, wherein said control circuit repeatedly and alternatingly supplies said first frequency control signal and said second frequency control signal to said frequency control terminal and repeatedly and alternatingly supplies said first antenna control signal and said second antenna control signal to said control input of said antenna until a detection signal is received or said predetermined time period has lapsed.
19. A trainable transmitter comprising:
an antenna for receiving an RF activation signal from a remote control transmitter for a remotely actuated device, the RF activation signal having an RF carrier frequency and code;
signal generating means having a frequency control terminal, said signal generator generates a reference signal having a reference frequency corresponding to a frequency control signal applied to said frequency control terminal, said signal generating means is coupled to said antenna for transmitting a modulated RF output signal having a carrier frequency related to the frequency control signal supplied to said frequency control terminal;
a demodulator coupled to said antenna and to an output of said signal generating means for demodulating the received RF activation signal using said reference signal, said demodulator including
a mixer having a first signal input terminal coupled to an output of said antenna for receiving the RF activation signal and having a second signal input terminal coupled to an output of said signal generating means for receiving said reference signal, said mixer providing a signal having the data code of the activation signal modulated at a modulation frequency representing a difference between the reference frequency and the carrier frequency of the RF activation signal, and
a filter having an input coupled to an output of said mixer for blocking all signals supplied to the filter input from said mixer except signals having a predetermined modulation frequency, said filter outputting the data code present in the received signal when the reference frequency and the carrier frequency of the activation signal have a predetermined relationship;
indicating means for providing an indication to a user that an RF activation signal is being received;
control means coupled to said filter for detecting the presence of a data code at an output of said filter, and coupled to said frequency control terminal of said signal generating means for supplying said frequency control signal, upon entering a training sequence, said control means changes the reference frequency of said reference signal from a lowest frequency to a highest frequency of a frequency range in which a valid carrier frequency of a received RF activation signal may be transmitted without changing the reference frequency to a discrete frequency that is intermediate said lowest and highest frequencies, said control means coupled to said indicating means for activation when a data code is detected at the output of said filter, upon detecting the presence of a data code, said control means changes the reference frequency of said reference signal step by step until a data code is again detected at the output of said filter, said control means identifies an RF carrier frequency of the received activation signal based upon the reference frequency at which a data code was detected, and stores the detected data code and frequency control data representing the RF carrier frequency of the received activation signal; and
an output circuit coupled to said control means, to said antenna, and to said signal generating means for supplying the stored data code to a data input terminal of said signal generating means and supplying a frequency control signal representing the stored frequency control data to the frequency control terminal of said signal generating means such that the carrier frequency of the modulated RF output signal transmitted by said signal generating means is the same as that of the RF activation signal received from the remote transmitter.
20. The trainable transmitter as defined in claim 19, wherein said filter includes:
a narrow bandpass filter coupled to said mixer for receiving all signal components output from said mixer as a result of mixing the received RF signal with the signal supplied from said signal generator, said bandpass filter filters all but a signal component output from said mixer having predefined carrier frequency, wherein the output of said mixer will have a signal component having the predefined carrier frequency when the frequency of said signal generated by said signal generator has a predefined relationship with the received RF activation signal; and
an integrator coupled to said bandpass filter for receiving and demodulating any output signal component from said bandpass filter to provide a detected data code to said control means.
21. The trainable transmitter as defined in claim 19, wherein said control means repeatedly and alternatingly varies the reference frequency output from said signal generating means to vary between said lowest frequency and said highest frequency, said control means continues to vary the reference frequency between said lowest and said highest frequencies until said control means detects the presence of a received signal within said frequency range or until a predetermined time period has expired.
22. The trainable transmitter as defined in claim 19 and further including an operator actuated switch coupled to said control means for controlling the operational state of said control means between idle and training modes, said control means controlling said signal generating means by supplying said frequency control signal to said frequency control terminal of said signal generating means when in said control means enters the training mode in response to an actuation of said switch by an operator.
23. The trainable transmitter as defined in claim 19 and further including an operator actuated switch coupled to said control means for controlling the operational state of said control means between idle and transmitting modes, said control means controlling said signal generating means by supplying said frequency control signal to said frequency control terminal of said signal generating means and by supplying the stored data code to said data input terminal of said signal generating means when said control circuit enters said transmitting mode in response to an actuation of said switch by an operator.
24. A method of training a vehicle transmitter to learn an RF carrier frequency and data code of an RF control signal received from a remote transmitter, for subsequent transmission of an RF signal having the learned RF carrier frequency and data code of the received RF control signal, said vehicle transmitter including an antenna and a receiver, said method comprising the sequentially performed steps of:
initiating a training sequence in response to an actuation of a switch;
monitoring an output of the antenna for an RF control signal within a predefined frequency band;
aborting the training sequence if an RF control signal within the predefined frequency band is not received within a predetermined time period;
if an RF control signal within the predefined frequency band is detected, discretely tuning the receiver to a series of frequencies within said predefined frequency band until an RF control signal is detected;
identifying the RF carrier frequency of the received RF control signal;
storing frequency control data representing the RF carrier frequency of the received RF control signal;
identifying the data code of the RF control signal; and
storing the identified data code of the received RF control signal.
25. The method of claim 24 further including the step of providing a user with an indication when an RF control signal within the predefined frequency band is received.
26. A method of training a vehicle transmitter to learn an RF carrier frequency and data code of an RF control signal received from a remote transmitter, for subsequent transmission of an RF signal having the learned RF carrier frequency and data code of the received RF control signal, said vehicle transmitter including an antenna and a tunable RF circuit, the method comprising the sequentially performed steps of:
monitoring an output of the antenna for an RF control signal within a predefined frequency band;
providing an indication when an RF control signal is being received within the predefined frequency band;
generating a reference signal having a first predetermined frequency;
comparing the reference signal to the received RF control signal to determine whether the frequency of the reference signal has a predetermined relationship to the RF carrier frequency of the received RF control signal;
changing the frequency of the reference signal until the frequency of the reference signal has the predetermined relationship to the RF carrier frequency of the received RF control signal;
identifying the RF carrier frequency of the received RF control signal based upon the frequency of the reference signal;
storing frequency control data representing the RF carrier frequency of the received RF control signal;
demodulating the received RF control signal using the generated reference signal having a frequency with the predetermined relationship to the RF carrier frequency to provide the data code of the RF control signal; and
storing the data code provided by demodulating the received RF control signal.
27. The method of claim 26, wherein said monitoring step includes the steps of:
generating a reference signal having said first frequency, which corresponds to the lowest frequency in the predefined frequency band;
generating a second reference signal having a second frequency corresponding to the highest frequency in the predefined frequency band to cause the tunable RF circuit to jump from being tuned to said first frequency to being tuned to said second frequency; and
detecting the presence of any received signal during the jump from the lowest to highest frequency.
28. The method of claim 27, wherein said monitoring step further includes the step of:
alternatingly generating reference signals of the lowest and highest frequencies until a predetermined time period lapses or the presence of any received signal is detected.
29. The method of claim 26, wherein the antenna of the vehicle transmitter is a dynamically tunable antenna and the monitoring step further includes the step of:
adjusting the resonant frequency at which the antenna is tuned to correspond to the lowest and highest frequencies of the reference signal in synchronism with the change in frequency of the reference signals.
30. A circuit for training a vehicle mounted RF transmitter to learn the RF carrier frequency and modulation scheme of an existing transmitter for subsequent transmission, said circuit including an RF circuit and a microprocessor programmed to control said RF circuit to sequentially perform the steps of:
initiate a rapid frequency scanning sequence of all frequencies lying within a frequency band;
provide the operator with an indication if an RF signal has been received;
training to the frequency and modulating scheme of a detected RF signal; and
aborting the training sequence in the event an RF signal is not detected during said rapid frequency scanning sequence.

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Fast scan trainable transmitter

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US Referenced Citations (51)

Foreign Referenced Citations (2)

Non-Patent Literature Citations (7)