SYSTEM AND METHOD FOR ANTICIPATORY RECEIVER SWITCHING BASED ON SIGNAL QUALITY ESTIMATION
In various embodiments, a first and second complex multiplier may be configured to receive an input signal and provide a baseband I component signal and a baseband Q component signal, respectively. A first and second filter may be configured to filter the baseband I component signal and the baseband Q component signal, respectively. An equalizer may be configured to equalize the filtered baseband I component signal and the filtered baseband Q component signal. A carrier recovery portion may be configured to generate a reference signal based on the equalized filtered baseband I component signal and the equalized filtered baseband Q component signal. A first and second multilevel comparator may be configured to receive the equalized filtered baseband I component signal from the carrier recovery portion and provide an output I and receive the equalized filtered baseband Q component signal and provide an output Q signal for further modulation.
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The present application is a continuation of, and claims priority under 35 U.S.C. §120 to, U.S. patent application Ser. No. 13/342,850, filed Jan. 3, 2012, entitled “System and Method for Anticipatory Receiver Switching Based on Signal Quality Estimation,” now U.S. Pat. No. 8,687,737, which is a continuation of, and claims priority under 35 U.S.C. §120 to, U.S. patent application Ser. No. 12/503,805, filed Jul. 15, 2009, entitled “System and Method for Anticipatory Receiver Switching Based on Signal Quality Estimation,” now U.S. Pat. No. 8,090,056, which is a continuation of, and claims priority under 35 U.S.C. § 120 to, U.S. patent application Ser. No. 11/452,216, filed Jun. 14, 2006, entitled “System and Method for Anticipatory Receiver Switching Based on Signal Quality Estimation,” now U.S. Pat. No. 7,570,713, each of which is incorporated herein by reference.
BACKGROUNDRadio communication systems are becoming more reliable, and the Mean Time Between Failure (MTBF) associated therewith is high. However, in microwave radio transmission, the associated transmission link may be long and multipath may be frequently encountered. Multipath refers to multiple transmission paths between transmit and receive antennas of a communication system. Multipath may result in both frequency-selective fading and space-selective fading. Frequency-selective fading generally indicates that a channel varies with frequency. Space-selective fading generally indicates that a channel is dependent upon the position of the respective transmit and receive antennas. When multipath interferes with reception of a radio transmission signal, the received signal is distorted causing errors in the corresponding demodulated data stream.
Advances in radio communication systems, however, require data transmission of larger volume at higher speeds. Accordingly, multiple value (M-ary) modulation methods having values larger than the 4 QAM modulation method described above have been developed. As an example of such an M-ary modulation method, 16 QAM is commonly employed in data communications.
When a modulation method having a larger M-ary number is employed and the communication environment of the propagation path is defective (i.e., if the propagation path has severe interference, noise or encounters multi-path), symbol points may be recognized erroneously since the interval between each of the symbol points is narrow and the symbol points are arranged tightly in the respective modulation method, as may be seen from the arrangement of symbol points of
In a radio communication environment prone to multipath, several known techniques may be implemented to mitigate the effects of multipath. Prior art techniques commonly used to protect a signal path include switching from an online channel, receiver or antenna to a standby channel, receiver or antenna by 1+1 Frequency Diversity (FD) or 1+1 Space Diversity (SD) or combination thereof.
SD may commonly be provided by utilizing multiple receive antennas separated by a sufficient distance to take advantage of space-selective fading. With reference to
The aforementioned diversity techniques and examples, however, are not always appropriate for evaluating the communication quality of the propagation path. For example, different radio reception apparatuses employ different methods of reception and performances. Qualities of components, such as filters used in the reception apparatuses, vary and such differences and variations have an influence on the quality of communication. Conventional parameters such as reception level, frame error rate, and carrier to interference ratios (CIR) do not reflect such quality or performances of the reception apparatuses. Further, as may be seen from a comparison of the modulation methods shown in
Thus, there is a need in the art for a system and method of selecting antennas or receivers in a multipath environment without incurring any errors in the received signal.
Accordingly, it is an object of the present subject matter to obviate many of the deficiencies in the prior art and to provide a novel method of switching from a first receiver receiving a constant bit rate signal to a second receiver receiving the constant bit rate signal, where the constant bit rate signal received by the first and second receivers is converted to a first baseband signal and a second baseband signal. The method further comprises the steps of estimating a signal quality metric of the first baseband signal, comparing the signal quality metric to a predetermined threshold, and switching from the first baseband signal to the second baseband signal if the signal quality metric is greater than the threshold.
It is also an object of the present subject matter to provide a novel method of switching from a first receiver receiving a constant bit rate signal to a second receiver receiving the constant bit rate signal, where the constant bit rate signal received by the first and second receivers is converted to a first baseband signal and a second baseband signal, respectively. The method further comprises the steps of estimating a first signal quality metric of the first baseband signal, estimating a second signal quality metric of the second baseband signal, comparing the first signal quality metric to the second signal quality metric, and switching from the first baseband signal to the second baseband signal if the first signal quality metric is greater than the second signal quality metric.
It is another object of the present subject matter to provide a novel system for switching from a first receiver receiving a constant bit rate signal to a second receiver receiving the constant bit rate signal. The system comprises a first converting circuit for converting the signal from the first receiver to a first baseband signal and a second converting circuit for converting the signal from the second receiver to a second baseband signal. The system further comprises an estimating circuit for estimating a first signal quality metric of the first baseband signal, a comparing circuit for comparing the first signal quality metric to a predetermined threshold, and a switching circuit for switching from the first baseband signal to the second baseband signal if the first signal quality metric is greater than the predetermined threshold.
It is still an object of the present subject matter to provide a novel system of switching from a first receiver receiving a constant bit rate signal to a second receiver receiving the constant bit rate signal comprising a first converting circuit for converting the signal from the first receiver to a first baseband signal and a second converting circuit for converting the signal from the second receiver to a second baseband signal. The system also comprises a first estimating circuit for estimating a first signal quality metric of the first baseband signal, a second estimating circuit for estimating a second signal quality metric of the second baseband signal, a comparing circuit for comparing the first signal quality metric to the second signal quality metric, and a switching circuit for switching from the first baseband signal to the second baseband signal if the first signal quality metric is greater than the second signal quality metric.
These and many other objects and advantages of the present invention will be readily apparent to one skilled in the art to which the invention pertains from a perusal of the claims, the appended drawings, and the following detailed description of the preferred embodiments.
SUMMARY OF THE INVENTIONIn various embodiments, a system comprises a first and second complex multiplier, a first and second filter, an equalizer, a carrier recovery portion, and a first and second multilevel comparator. The first complex multiplier may be configured to receive an input signal and provide a baseband I component signal. The second complex multiplier may be configured to receive the input signal and provide a baseband Q component signal. The first filter may be configured to filter the baseband I component signal. The second filter may be configured to filter the baseband Q component signal. The equalizer may be configured to equalize the filtered baseband I component signal and to equalize the filtered baseband Q component signal. The carrier recovery portion may be configured to generate a reference signal based on the equalized filtered baseband I component signal and the equalized filtered baseband Q component signal. The first multilevel comparator may be configured to receive the equalized filtered baseband I component signal from the carrier recovery portion and provide an output I signal for further demodulation. The second multilevel comparator may be configured to receive the equalized filtered baseband Q component signal from the carrier recovery portion and provide an output Q signal for further demodulation.
The system may further comprise a lookup table (LUT) wherein the LUT provides a sine signal to the first complex multiplier and a cosine signal to the second complex multiplier. The sine signal and the cosine signal may be based on the reference signal from the carrier recovery portion. Further, the sine signal may be substantially the same carrier frequency and is in phase with the input signal and the cosine signal may be substantially the same carrier frequency and is in quadrature phase with the input signal.
The system may also further comprise a signal quality estimation circuit configured to estimate a signal quality based on the filtered baseband I component signal and the filtered baseband Q component signal. The signal quality estimation circuit may be configured to estimate a signal quality based on the equalized filtered baseband I component signal and the equalized filtered baseband Q component signal. Further, the signal quality estimation circuit may be configured to estimate a signal quality based on the equalized filtered baseband I component signal received form the carrier recovery portion and the equalized filtered baseband Q component signal received from the carrier recovery portion.
The signal quality estimation circuit may comprise a distance calculator, an average calculator, and a comparator. The distance calculator may be configured to determine a distance between an ideal symbol and a received symbol of the equalized filtered baseband I component signal and the equalized filtered baseband Q component signal. The average calculator may be configured to determine an average distance between based on the distance from the distance calculator. The comparator may be configured to compare the average distance to a predetermined threshold. The signal quality estimation circuit may be further configured to generate an alert signal when a quality is low based on the comparison of the average distance to the predetermined threshold.
In various embodiments, a method may comprise multiplying an input signal with a sine signal to provide a baseband I component signal, multiplying the input signal with a cosine signal to provide a baseband Q component signal, filtering the baseband I component signal, filtering the baseband Q component signal, equalizing the filtered baseband I component signal, equalizing the filtered baseband Q component signal, generating a reference signal based on the equalized filtered baseband I component signal and the equalized filtered baseband Q component signal, comparing the equalized filtered baseband I component signal to provide an output I signal for further demodulation, and comparing the equalized filtered baseband Q component signal to provide an output Q signal for further demodulation.
A system may comprise a means for multiplying an input signal with a sine signal to provide a baseband I component signal, a means for multiplying the input signal with a cosine signal to provide a baseband Q component signal, a means for filtering the baseband I component signal, a means for filtering the baseband Q component signal, a means for equalizing the filtered baseband I component signal, a means for equalizing the filtered baseband Q component signal, a means for generating a reference signal based on the equalized filtered baseband I component signal and the equalized filtered baseband Q component signal, a means for comparing the equalized filtered baseband I component signal to provide an output I signal for further demodulation, and a means for comparing the equalized filtered baseband Q component signal to provide an output Q signal for further demodulation.
With reference to the figures where like elements have been given like numerical designations to facilitate an understanding of the present invention, the various embodiments of a system and method for switching from a first receiver to a second receiver without error in a received signal by utilizing signal quality estimation are described. Switching according to embodiments of the present subject matter may be conducted in conjunction with 1+1 or 1 for N protected radio links or other transmission media to thereby protect against signal path disturbance, equipment degradation or equipment failure and to achieve high data availability carried through such media. Furthermore, embodiments of the present subject matter estimate signal quality of a received signal derived from the decision directed coherent demodulation of M-ary/M-state QAM/PSK (i.e., 4 QAM (PSK) to 256 QAM (PSK) or higher).
A system and method according to the present subject matter may utilize an exemplary signal quality estimation circuit illustrated by
The demodulator circuit 300 receives a modulated IF signal 310. The modulated IF signal 310 is provided to complex multipliers 320, 322 which provide baseband I and Q component signals 324 and 326, respectively. A sine/cosine look-up table (LUT) 330 provides sine and cosine signals, sin(x) and cos(x), 316 and 318 respectively, to the complex multipliers 320, 322. The phase components of the sine and cosine signals are such that the multiplication of the modulated IF signal 310 to form I and Q components followed by an appropriate filtering 340, 341 (i.e., low pass, loop or other well known filters) provide I and Q signals 342 and 344, respectively.
The signals 342, 344 are provided to an equalizer 350 which processes the signals and passes equalized signals to a carrier recovery portion 360 of the demodulator circuit 300. Broadly, the equalizer 350 processes and/or filters the received signals 342, 344 to reduce or eliminate intersymbol interference (ISI). An equalizer according to an embodiment of the present subject matter may conduct maximum likelihood sequence estimation, filter equalization (i.e., linear, non-linear filters), or other forms of equalization known in the art. The carrier recovery portion 360, as is known in the art, creates a reference signal for input into the LUT 330 which, in turn, outputs a signal 316 having a frequency that is substantially the same as the carrier frequency and is in phase with the carrier signal, and outputs a signal 318 having a frequency that is substantially the same as the carrier frequency but is out of phase (quadrature) with the carrier signal. The carrier recovery portion 360 provides equalized I and Q signals 362 and 364, respectively, from the equalizer 350 to multilevel comparators 372, 374 and a signal quality estimation circuit 376. Of course, the demodulator circuit 300 may include various other components such as a slope equalizer, a DC offset compensation circuit, converters, gain compensation circuits, clock recovery circuits, demapper circuits, forward error correction circuits, and combinations thereof, as well as other demodulator components known in the art. Furthermore, the sensing connections for the signal quality estimation circuit 376 may be moved to the output of the filters 340, 341 or the output of the equalizer 350. The demodulator circuit 300 may thus accurately estimate the signal quality for different modulation levels and different FEC coding schemes such as 2D TCM, 4D TCM, Reed Solomon code, and concatenation of TCM and Reed Solomon code. Of course, the demodulator circuit 300 may be implemented through hardware or software or a combination of both hardware and software.
For example,
With reference to
The DADE circuit 640 compensates for any delay between the two data streams provided by the receivers and aligns the data streams so that a data transition from an active channel to a standby channel occurs without error. For example, when switching occurs, the two data streams provided by the receivers must be aligned so that the transition of data from one receiver to the data from a second receiver occurs without error. The DADE circuit may comprise two delay flip-flop buffers. One buffer delays data signals from one receiver and the second buffer delays data signals from the second receiver. Since the signal carried by the two receivers possesses disparate paths (i.e., the signals pass through different hardware), there exists some delay between the two signals. The DADE circuit may constantly monitor and align the two data streams from the two receivers. The active channel or receiver buffer will be read and outputted at the center of the buffer while the data from the standby channel or receiver is altered to possess the same delay as that of the active channel or receiver. The DADE circuit may also dynamically correct the delay alignment if one or both receivers experience a multipath (selective) fading that sifts the data around. When switching occurs, the selected buffer outputs the data to the following circuit for further processing. Since the two incoming signals to the DADE circuit possess different delay and phase, the read clock for both buffers is synchronized by the incoming clock of the selected channel. In the event of a sudden phase jump of the read clock resulting in a phase hit and synchronization loss for the following circuit, the phase transition of the read clock should be slow enough to mitigate any phase hits. This may be achieved by appropriately utilizing a phase locked loop.
An exemplary communications system according to an embodiment of the present subject matter receives a constant bit rate signal at the antennas which is then provided to the receivers. The constant bit rate signal received by the receivers is converted to a first baseband signal and a second baseband signal, respectively, and the demodulator estimates a signal quality metric of the first baseband signal, compares the signal quality metric to a predetermined threshold, and provides alarm information to the CPU. The CPU evaluates the alarm information provided by the demodulator and provides switching control information to the DADE circuit or other suitable switching circuit if the signal quality metric exceeds a predetermined threshold to thereby switch from the first baseband signal to the second baseband signal. The demodulator may estimate the first signal quality metric by determining a first distance between a location of a first symbol of the first baseband signal and a first predetermined ideal symbol location, determining a second distance between a location of a second symbol of the first baseband signal and a second predetermined ideal symbol location, and determining an average distance for the first and second distance determinations whereby the average distance may be compared to the predetermined threshold to generate the alarm information.
In a further embodiment, the demodulator may estimate the first signal quality metric by determining, for each of n symbols of the first baseband signal, a distance between a location of the symbol and an associated predetermined ideal symbol location, determining a sum of the distances for the n symbols, and dividing the sum by n whereby the sum divided by n may be compared to a predetermined threshold to generate the alarm information.
A communications system according to a further embodiment of the present subject matter receives a constant bit rate signal at the antennas which are then provided to the receivers. The constant bit rate signal received by the receivers is converted to a first baseband signal and a second baseband signal, respectively. A first demodulator estimates a signal quality metric of the first baseband signal, and a second demodulator estimates a signal quality metric of the second baseband signal. The CPU compares the first signal quality metric to the second signal quality metric and provides switching control information to the DADE circuit or another suitable switching circuit if the signal quality metric exceeds a predetermined threshold to thereby switch from the first baseband signal to the second baseband signal. The first demodulator may estimate the first signal quality metric by determining a first distance between a location of a first symbol of the first baseband signal and a first predetermined ideal symbol location, determining a second distance between a location of a second symbol of the first baseband signal and a second predetermined ideal symbol location, and determining a first average distance for the first and second distance determinations. The second demodulator may estimate the second signal quality metric by determining a third distance between a location of a first symbol of the second baseband signal and a third predetermined ideal symbol location, determining a fourth distance between a location of a second symbol of the second baseband signal and a fourth predetermined ideal symbol location, and determining a second average distance for the third and fourth distance determinations whereby the first average distance may be compared to the second average distance to generate the alarm information.
In a further embodiment, the first demodulator may estimate the first signal quality metric by determining, for each of n symbols of the first baseband signal, a distance between a location of the symbol and an associated predetermined ideal symbol location, determining a first sum of the distances for the n symbols, and dividing the first sum by n. Similarly, the second demodulator may estimate the second signal quality metric by determining, for each of n symbols of the second baseband signal, a distance between a location of the symbol and an associated predetermined ideal symbol location, determining a second sum of the distances for the n symbols, and dividing the second sum by n whereby the first sum divided by n is compared to the second sum divided by n to generate the alarm information. Of course, the first and second signal quality metrics may be compared to predetermined thresholds rather than to each other. For example, the first signal quality metric may be compared to a predetermined threshold and if the first signal quality metric is greater than a predetermined threshold then the second signal quality metric may be compared to a predetermined threshold. If the second signal quality metric is less than the predetermined threshold, then the CPU may provide switching control information to the DADE circuit or another suitable switching circuit to thereby switch from the first baseband signal to the second baseband signal. However, if the second signal quality metric is greater than or equal to the predetermined threshold, the first signal quality metric may be compared to the second signal quality metric, and the CPU may provide switching control information to the DADE circuit or another suitable switching circuit to thereby switch from the first baseband signal to the second baseband signal if the first signal quality metric is greater than the second signal quality metric.
For example, when multipath occurs to a wide band spectrum, a slope with various steepness will occur to the affected spectrum while selective fading may sweep through the spectrum. With proper adaptive slope equalization, the slope in the spectrum may be corrected to a certain extent. When slope equalization reaches its correction limit, a slope alarm will be declared, which may be used to switch to a standby receiver. However, when the spectrum is narrow, relatively flat fading occurs during multipath occurrence. Thus, slope alarm may not be as reliable against multipath occurrences for narrow band signal.
By way of further example, FEC decoding generates syndromes for convolutional decoders or corrected symbols in Reed Solomon decoders when transmission errors occur, which may be used to trigger receiver switching. However, comparing the relative signal quality between the two may be a relatively slow process. Thus, switching from this information may be too slow to ensure a reliable errorless switch for lower capacity data during fast fading periods. Thus, other events may be used to initiate receiver switching, such as BER alarm, etc. Thus, in another aspect of the present subject matter, a signal quality degrade threshold to trigger the switching may be set such that an alarm will be triggered before any error appears at an FEC decoder output.
In a multipath environment, selective fading may sweep through a receiver antenna with progressive speed. However, with a 1+1 protected FD system 700 according to an embodiment of the present subject matter, the two RF carriers are sufficiently separated in frequency and thus, the signal distortion will occur to one carrier and then to the next carrier, but not both simultaneously. Furthermore, with a 1+1 protected SD system 600 according to an embodiment of the present subject matter, the two receive antennas 604, 606 are properly displaced and thus, selective fading will affect one of the two antennas, but not both simultaneously. Thus, with FD or SD systems or combinations thereof, error free data transmission can be ensured even during severe path disturbance period.
In a further aspect of the present subject matter, the system may incorporate Adaptive Time Domain Equalization (ATDE) and/or forward error correction (FEC) such that the alarm information and subsequent receiver switching will occur before any error occurs to output data during signal path fading (selective or flat fading). Thus, in conjunction with a DADE circuit, switching from a degraded active channel to a good standby channel may be completed without any error.
Although embodiments of the present subject matter have been described with application to 4 QAM, it is to be understood that the present subject matter is applicable for M-ary QAM systems and M-state PSK systems, i.e., embodiments of the present subject matter may be utilized in any M-ary QAM demodulator (M=4, 8, 16, 32, 64, 128, 256, etc.) and may be utilized in any M-state PSK demodulator (M=2, 4, 8, 16, 32, 64, 128, 256, etc.). Furthermore, it is to be understood that embodiments of the present subject matter may also be utilized in any non conventional 2 dimensional (I-Q) modulation.
As shown by the various configurations and embodiments illustrated in
While preferred embodiments of the present subject matter have been described, it is to be understood that the embodiments described are illustrative only and that the scope of the invention is to be defined solely by the appended claims when accorded a full range of equivalence, many variations and modifications naturally occurring to those of skill in the art from a perusal hereof.
Claims
1-12. (canceled)
13. A system, comprising:
- a first estimating circuit for estimating a first signal quality metric of a first signal, the first signal quality metric being based on a distance signal that is a function of a distance between a real symbol location of a real symbol of the first signal and an associated predetermined ideal symbol location of an ideal symbol;
- a comparing circuit for comparing the first signal quality metric to a predetermined threshold to determine whether the first signal quality metric meets a signal quality, and for providing an alarm indicator when the first signal quality metric does not meet the signal quality;
- a flag circuit for determining whether the alarm indicator from the comparing circuit satisfies an alarm condition; and
- a switching circuit for switching from the first signal to a second signal in response to satisfaction of the alarm condition, the second signal being substantially independent of the first signal.
14. The system of claim 13, wherein the first and second signals are baseband signals.
15. The system of claim 13, wherein the switching circuit is configured to switch from the first signal to the second signal based on one or more of: intermediate frequency (IF) spectrum information, IF slope information, bit-error-rate (BER) information, signal degradation information, and signal outage information.
16. The system of claim 15, wherein the signal degradation information is provided by a forward-error-coding (FEC) process.
17. The system of claim 13, wherein the switching circuit is configured to switch from the first signal to the second signal according to a switching request priority associated with the comparison of the first signal quality metric to the predetermined threshold and other signal quality information.
18. The system of claim 17, wherein the switching request priority comprises bit-error-rate (BER), frame loss, signal degradation, intermediate frequency (IF) slope, or low receiver signal level (RSL) sensed at a radio antenna port.
19. The system of claim 13, wherein the switching circuit comprises a differential absolute delay equalizer (DADE) circuit configured to compensate for delay between the first signal and the second signal.
20. The system of claim 19, wherein the DADE circuit is configured to dynamically correct the delay if a first receiver associated with the first signal experiences multipath fading.
21. The system of claim 13, wherein the flag circuit is configured to determine whether the alarm indicator satisfies the alarm condition continuously, or at a predetermined interval.
22. A method, comprising:
- estimating a first signal quality metric of a first signal, the first signal quality metric being based on a distance signal that is a function of a distance between a real symbol location of a real symbol of the first signal and an associated predetermined ideal symbol location of an ideal symbol;
- comparing the first signal quality metric to a predetermined threshold to determine whether the first signal quality metric meets a signal quality;
- providing an alarm indicator when the first signal quality metric does not meet the signal quality;
- determining whether the alarm indicator satisfies an alarm condition; and
- switching from the first signal to a second signal in response to satisfaction of the alarm condition, the second signal being substantially independent of the first signal.
23. The method of claim 22, wherein the first and second signals are baseband signals.
24. The method of claim 22, wherein the switching from the first signal to the second signal comprises switching from the first signal to the second signal based on one or more of:
- intermediate frequency (IF) spectrum information, IF slope information, bit-error-rate (BER) information, signal degradation information, and signal outage information.
25. The method of claim 24, wherein the signal degradation information is provided by a forward-error-coding (FEC) process.
26. The method of claim 22, wherein the switching from the first signal to the second signal comprises switching from the first signal to the second signal according to a switching request priority associated with the comparison of the first signal quality metric to the predetermined threshold and other signal quality information.
27. The method of claim 26, wherein the switching request priority comprises bit-error-rate (BER), frame loss, signal degradation, intermediate frequency (IF) slope, or low receiver signal level (RSL) sensed at a radio antenna port.
28. The method of claim 22, wherein the switching from the first signal to the second signal comprises compensating for delay between the first signal and the second signal.
29. The method of claim 28, wherein the compensating for delay between the first signal and the second signal comprises dynamically correcting the delay if a first receiver associated with the first signal experiences multipath fading.
30. The method of claim 22, wherein the determining whether the alarm indicator satisfies the alarm condition comprises determining whether the alarm indicator satisfies the alarm condition continuously, or at a predetermined interval.
31. A system, comprising:
- means for estimating a first signal quality metric of a first signal, the first signal quality metric being based on a distance signal that is a function of a distance between a real symbol location of a real symbol of the first signal and an associated predetermined ideal symbol location of an ideal symbol;
- means for comparing the first signal quality metric to a predetermined threshold to determine whether the first signal quality metric meets a signal quality;
- means for providing an alarm indicator when the first signal quality metric does not meet the signal quality;
- means for determining whether the alarm indicator satisfies an alarm condition; and
- means for switching from the first signal to a second signal in response to satisfaction of the alarm condition, the second signal being substantially independent of the first signal.
Type: Application
Filed: Mar 31, 2014
Publication Date: Aug 14, 2014
Applicant: AVIAT U.S., INC. (Santa Clara, CA)
Inventors: Tjo San Jao (Beaconfield), Richard Bourdeau (Saint-Laurent)
Application Number: 14/231,199
International Classification: H04B 7/08 (20060101);