Patent Grant
10008109
The invention relates generally to a system and method for training a programmable transceiver.
Certain vehicles include a programmable transceiver configured to operate a variety of remote devices. In certain configurations, the programmable transceiver is configured to receive a training signal from a training transmitter, and to store the training signal within a memory. In such configurations, subsequent activation of the programmable transceiver broadcasts a signal that substantially corresponds to the training signal. As a result, the programmable transceiver may operate a remote device associated with the training transmitter. By way of example, to train a programmable transceiver to operate a garage door opener, a transmitter associated with the garage door opener is positioned proximate to the programmable transceiver. The programmable transceiver is then placed into a training mode, in which the programmable transceiver scans typical transmitter frequencies until a signal is detected. The programmable transceiver then stores information associated with the signal within the memory, thereby enabling the programmable transceiver to simulate the garage door opener transmitter upon subsequent activation.
As will be appreciated, transmitters may operate within a variety of frequency ranges. For example, certain transmitters may broadcast signals within a range of about 285 MHz to about 440 MHz. Other transmitters may broadcast signals within a range of about 867 MHz to about 869 MHz. Consequently, as the programmable transceiver scans frequencies within a desired range, the programmable transceiver may detect a harmonic frequency or a subharmonic frequency of the training signal fundamental frequency. As a result, the programmable transceiver may be trained based on the subharmonic or harmonic frequency. Accordingly, subsequent activation of the programmable transceiver may broadcast a signal at an incorrect frequency. For example, if the training transmitter broadcasts a signal at about 868 MHz, and the programmable transceiver scans a frequency range of about 285 MHz to about 440 MHz, the programmable transceiver may detect a subharmonic frequency of the training signal at about 434 MHz. Consequently, the programmable transceiver may be trained based on the signal at the subharmonic frequency. As a result, subsequent activation of the programmable transceiver may not activate the remote device associated with the training transmitter because the signal broadcast by the programmable transceiver is at an incorrect frequency.
The present invention relates to a method for training a programmable transceiver including scanning frequencies within a desired range for a first signal, and detecting the first signal at a first frequency. The method also includes computing harmonic frequencies and subharmonic frequencies of the first frequency, and scanning the harmonic frequencies and the subharmonic frequencies for a second signal at a second frequency. The method further includes comparing a first magnitude of the first signal to a second magnitude of the second signal. In addition, the method includes training the programmable transceiver based on the second signal if the second magnitude is greater than the first magnitude, otherwise training the programmable transceiver based on the first signal.
The present invention also relates to a programmable transceiver including a controller configured to scan frequencies within a desired range for a first signal, and to detect the first signal at a first frequency. The controller is also configured to compute harmonic frequencies and subharmonic frequencies of the first frequency, and to scan the harmonic frequencies and the subharmonic frequencies for a second signal at a second frequency. In addition, the controller is configured to compare a first magnitude of the first signal to a second magnitude of the second signal, and to train the programmable transceiver based on the second signal if the second magnitude is greater than the first magnitude, and to otherwise train the programmable transceiver based on the first signal.
The present invention further relates to a programmable transceiver including a transceiver configured to receive a training signal from a training transmitter, and a memory configured to store information associated with the training signal. The programmable transceiver also includes a controller configured to instruct the transceiver to scan frequencies within a desired range for a first signal, and to detect the first signal at a first frequency. The controller is also configured to compute harmonic frequencies and subharmonic frequencies of the first frequency, and to instruct the transceiver to scan the harmonic frequencies and the subharmonic frequencies for a second signal at a second frequency. In addition, the controller is configured to compare a first magnitude of the first signal to a second magnitude of the second signal, and to establish the training signal based on the second signal if the second magnitude is greater than the first magnitude, and to otherwise establish the training signal based on the first signal. The controller is also configured to store the information associated with the training signal in the memory.
By way of example, an operator may initiate the training process by depressing an unassigned button 34 of the programmable transceiver 22. The operator then places the training transmitter 36 in proximity to the programmable transceiver 22, and engages a switch 38 on the training transmitter 36, thereby activating a transmitter 40. The transmitter 40 broadcasts a signal to the transceiver 28 including information associated with activation of a remote device 42. For example, the information may include a security code configured to block unauthorized users from activating the remote device 42. To detect the training signal, the controller 30 instructs the transceiver 28 to scan frequencies within a desired range for the training signal broadcast by the transmitter 40. For example, the controller 30 may instruct the transceiver 28 to scan upwardly through the desired range by a fixed frequency increment, and downwardly through the desired range by the fixed frequency increment until a signal is detected.
Upon detection of the signal, the controller 30 computes harmonic frequencies and subharmonic frequencies of the detected signal frequency. In certain embodiments, the controller 30 is configured to determine whether each computed harmonic and subharmonic frequency is within an expected frequency range (e.g., within a frequency range of known transmitters). If the computed frequency is within the expected range, the controller 30 instructs the transceiver 28 to scan the frequency for a second signal. If a second signal is detected, the controller 30 compares a first magnitude of the first signal to a second magnitude of the second signal. A greater first magnitude indicates that the first signal is broadcast at a fundamental frequency, and the second signal corresponds to a harmonic or subharmonic frequency. Conversely, a greater second magnitude indicates that the second signal is broadcast at a fundamental frequency, and the first signal corresponds to a harmonic or subharmonic frequency. Consequently, if the second magnitude is greater than the first magnitude, the controller 30 establishes the training signal based on the second signal. Otherwise, the controller 30 establishes the training signal based on the first signal. The controller 30 then stores the information associated with the training signal in the memory 32. For example, the controller 30 may assign the information associated with the training signal to the unassigned button previously depressed by the operator.
While the process described above relates to assigning information associated with a training signal to an unassigned button, it should be appreciated that signal information may also be assigned to a previously assigned button. For example, in certain embodiments, depressing a previously assigned button for a particular duration (e.g., about 20 seconds) induces the programmable transceiver to enter a training mode. In such embodiments, information associated with a training signal may be assigned to the previously assigned button by depressing the previously assigned button for the particular duration, and then activating the training transmitter. In this manner, the information associated with the training signal is assigned to a desired button, thereby enabling the button to activate a remote device.
Once the information associated with the training signal is stored within the memory 32, subsequently depressing the assigned button instructs the transceiver 28 to broadcast the information associated with the training signal, thereby activating the remote device 42. For example, in certain embodiments, the remote device 42 may be a garage door opener having a receiver 44, and an actuator 46. Upon receiving the information associated with the training signal at the expected frequency, the receiver 44 instructs the actuator 46 to drive a garage door to open or close. In this manner, the programmable transceiver 22 may be utilized instead of the training transmitter 36 to control the remote device 42.
In certain embodiments, the signal information may include data indicative of the signal frequency. For example, if the training transmitter broadcasts a training signal at 868 MHz, the signal information may include data indicative of an 868 MHz broadcast frequency. Accordingly, if the programmable transceiver detects a signal at 434 MHz, the controller may determine that the detected signal is at a subharmonic frequency of the training signal frequency based on the information within the training signal indicating that the signal frequency is 868 MHz. As a result, the programmable transceiver may be trained based on the fundamental frequency of the training transmitter, thereby substantially reducing or eliminating the possibility of training the programmable transceiver based on an incorrect frequency.
The process of scanning frequencies within the desired range continues until one or more signals are detected, as represented by block 52. If multiple signals are detected within the desired range, the signal having the greatest magnitude is selected as the detected signal, as represented by block 54. For example, the programmable transceiver may receive multiple signals from various transmitters operating within a detectable range of the transceiver. However, because the training transmitter is positioned proximate to the programmable transceiver, the magnitude of the training transmitter signal may be higher than the magnitude of signals from more remote transmitters. Accordingly, selecting the signal having the greatest magnitude substantially reduces or eliminates the possibility of training the programmable transceiver based on a detected ambient signal.
Next, as represented by block 56, a magnitude of the detected signal is compared to a threshold value. As will be appreciated, the magnitude of harmonic frequencies and subharmonic frequencies is less than the magnitude of the corresponding fundamental frequency. Accordingly, if the detected signal has a magnitude that approaches the maximum output power of the training transmitter, the frequency of the detected signal corresponds to the fundamental broadcast frequency of the training transmitter. In the illustrated embodiment, the threshold value is selected based on the expected maximum output power to the training transmitter. Therefore, if the magnitude of the detected signal is greater than the threshold value, the programmable transceiver is trained based on the detected signal, as represented by block 58. In certain embodiments, the threshold value may be greater than 50 dB, 70 dB, 90 dB, or 100 dB, for example.
If the magnitude of the detected signal is less than or equal to the threshold value, harmonic frequencies and subharmonic frequencies of the detected signal frequency are computed, as represented by block 60. As will be appreciated, harmonic frequencies are frequencies that correspond to a multiple of the detected frequency, and subharmonic frequencies are frequencies that correspond to an inverse multiple (e.g., 1/n, 2/n, etc.) of the detected frequency. For example, harmonic frequencies may be 3/2, 2, or 3 times the fundamental frequency, and subharmonic frequencies may be ⅓, ½, or ⅔ of the fundamental frequency. By way of example, a signal having a 300 MHz fundamental frequency may include harmonic frequencies of 600 MHz, 900 MHz, and 1200 MHz, and subharmonic frequencies of 150 MHz, 100 MHz, and 75 MHz. To limit the number of scanned harmonic frequencies and subharmonic frequencies, the computed frequencies are compared to an expected frequency range, as represented by block 62, and only frequencies corresponding to the expected range are scanned, as represented by block 64.
For example, in certain embodiments, the desired frequency range includes frequencies from about 285 MHz to about 440 MHz, and the expected range includes frequencies within the desired frequency range, and frequencies from about 867 MHz to about 869 MHz, and from about 900 MHz to about 930 MHz. By way of example, if a frequency of about 434 MHz is detected, only one harmonic frequency, 868 MHz, is scanned because 868 MHz is the only harmonic frequency within the expected range. In addition, only one subharmonic frequency, 289.333 MHz, is scanned because 289.333 MHz is the only subharmonic frequency within the expected range. In further embodiments, the desired frequency range is about 867 MHz to about 869 MHz, and about 900 MHz to about 930 MHz, and the expected range includes frequencies within the desired frequency range, and frequencies from about 285 MHz to about 440 MHz. By way of example, if a frequency of about 900 MHz is detected, only one subharmonic frequency, 300 MHz, is scanned because 300 MHz is the only subharmonic frequency within the expected range. In addition, no harmonic frequencies are scanned because no harmonic frequency is within the expected range. While two desired frequency ranges and two expected frequency ranges are described above, it should be appreciated that other desired and expected ranges may be scanned in alternative embodiments.
Next, as represented by block 66, the magnitude of the signal at the computed frequency is compared to the magnitude of the detected signal. If the magnitude of the signal at the computed frequency is less than the magnitude of the detected signal, the programmable transceiver is trained based on the detected signal, as represented by block 58. Conversely, if the magnitude of the signal at the computed frequency is greater than the magnitude of the detected signal, the programmable transceiver is trained based on the signal at the computed frequency, as represented by block 68. In this manner, the possibility of training the programmable transceiver based on a signal at an incorrect frequency is substantially reduced or eliminated, thereby enabling the programmable transceiver to accommodate a wide variety of frequency ranges.
In certain embodiments, the sensitivity of the programmable transceiver may vary as a function of frequency. For example, the programmable transceiver may be more sensitive to frequencies within a range of about 867 MHz to about 869 MHz, and about 900 MHz to about 930 MHz, than to frequencies within a range of about 285 MHz to about 440 MHz. Consequently, a correction factor may be applied to the magnitude of a detected signal to compensate for the frequency dependent sensitivity variations. By way of example, if the programmable transceiver detects a signal at 434 MHz, the programmable transceiver may scan 868 MHz to determine if the detected signal (at 434 MHz) is the fundamental broadcast frequency of the training transmitter or a subharmonic frequency. However, if the programmable transceiver is more sensitive to 868 MHz than to 434 MHz, a correction factor may be applied to the magnitude of the higher frequency signal and/or to the magnitude of the lower frequency signal to facilitate an accurate comparison of the signal magnitudes. In this manner, the broadcast magnitudes, as compared to the detected magnitudes, may be compared to determine the stronger signal, thereby enhancing the probability that the programmable transceiver is trained based on the fundamental frequency of the training transmitter. By way of example, a correction factor of about +18 dB may be applied to signals having a frequency around 300 MHz, a correction factor of about +9 dB may be applied to signals having a frequency around 360 MHz or around 430 MHz, and a correction factor of about 0 dB may be applied to signals having a frequency around 868 MHz.
While only certain features and embodiments of the invention have been illustrated and described, many modifications and changes may occur to those skilled in the art (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperatures, pressures, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited in the claims. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention. Furthermore, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not have been described (i.e., those unrelated to the presently contemplated best mode of carrying out the invention, or those unrelated to enabling the claimed invention). It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure, without undue experimentation.
The present application is a U.S. National Stage of International Application No. PCT/US2012/068209 filed on Dec. 6, 2012, which claims the benefit of Provisional Patent Application No. 61/568,728 filed on Dec. 9, 2011, the entire disclosures of all of which are incorporated herein by reference.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/US2012/068209 | 12/6/2012 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2013/086166 | 6/13/2013 | WO | A |
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| Number | Date | Country | |
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| 20150009021 A1 | Jan 2015 | US |
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