WO1992010882A1 - Seamless frequency hopping system - Google Patents
Seamless frequency hopping system Download PDFInfo
- Publication number
- WO1992010882A1 WO1992010882A1 PCT/US1991/006347 US9106347W WO9210882A1 WO 1992010882 A1 WO1992010882 A1 WO 1992010882A1 US 9106347 W US9106347 W US 9106347W WO 9210882 A1 WO9210882 A1 WO 9210882A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- frequency hopping
- audio
- radio
- hopping system
- hop
- Prior art date
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Classifications
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/69—Spread spectrum techniques
- H04B1/713—Spread spectrum techniques using frequency hopping
Definitions
- the present invention is related to 0 communication systems and more specifically to reducing interference while communicating by utilizing frequency hopping.
- This interference can be any electrical or electromagnetic disturbance, phenomena, signal, or emission, man-made or natural, which causes or can
- a seamless frequency hopping system which incorporates the concepts of audio time compression, hop by hop automatic gain control and time repeating j e squelch to improve the sound of frequency hopped analog communication.
- the system is implemented by utilizing a digital signal processor with its associated electronics in conjunction with a frequency hopping radio.
- Figure 1 illustrates a hardware block diagram of the present invention
- m m Figure 2 illustrates frequency hopping audio time compression.
- Figure 3 illustrates a transmit algorithm for frequency hopping.
- Figure 4 illustrates the contents of a transmit 30 hop frame after processing.
- Figure 5 illustrates a receive algorithm for frequency hopping.
- Figure 6 illustrates magnitude response of an ideal interpolation low pass filter.
- a seamless frequency hopping system which 5 utilizes a digital signal processor (DSP) that time compresses voice during a single frequency dwell and then expands it to completely fill the dwell time including the hop dead time.
- DSP digital signal processor
- the effect is no change in the audio l ⁇ output from single frequency operation to frequency hopping operations. Therefore, the hopping operation is nearly transparent to the radio operator/pilot and the operator does not hear the annoying repetition- rate clicks associated with a typical hopping ic operation.
- DSP programmable digital signal processor
- 25 can be an ATT 7522 codec or any similar device having an analog to digital converter and an anti-aliasing filter.
- input interface circuitry for example, input interface circuitry
- input interface circuitry 13 the signal follows, in a serial manner, line 15 which connects input interface circuitry 13 with digital signal processor 11.
- Digital signal processor 11 which may be an ATT DSP32C or any similar device, interfaces to a
- Digital signal processor 11 also interfaces with memory 12 through address line 18 and data line 19 in a manner which is known by one skilled in the art. Digital signal processor 11 with memory 12 performs software 5 processing as discussed below. Memory 12 in this example is a 4Kx32 EEPROM, but may be any similar storage device. After software processing, an output from digital signal processor 11 follows, in a serial manner, output line 20. Output line 20 connects ! Q digital signal processor 11 with output interface circuitry 21. Output interface circuitry 21 can be an AT&T 7522 codec or any similar device having a digital to analog converter and an anti-aliasing filter.
- the -, processed signal flows out of the seamless frequency hopping system on analog output line 22 to a frequency hopping radio 10.
- the system will sense when the radio is transmitting via transmit/ receive line 16. When transmitting, the system receives audio from the radio microphone port via input line
- the system When receiving, the system receives audio in from the radio receiver via input line 14 and outputs audio to the radio audio amplifier via output line 22.
- the multiplexing of these analog 5 lines is handled external to the system by the radio.
- FIG. 2 The concepts of seamless frequency hopping are illustrated in Figure 2.
- incoming uncompressed audio is first sliced into time 30 segments that each correspond to one frequency hop.
- the uncompressed audio is then compressed to a certain percentage of its original length in time.
- a dead time as well as a pilot signal are added to the front of the audio.
- the pilot signal is used for 5 synchronization, automatic gain control (AGC) , squelch and algorithm activation.
- AGC automatic gain control
- squelch squelch and algorithm activation
- a second radio receives the incoming signal and demodulates it to once again become an audio signal. 5
- the received audio is first passed through a correlator to detect the pilot signal that was inserted at the front of the hopped audio.
- the peak output from the correlator is used to set the gain control and the squelch for the entire hop. If that o output is too low, then the pilot signal wasn't detected and the audio signal from the previous hop is replicated for this hop. This process is known as "repetitive squelch”. If the correlator peak output passes a certain threshold, then the pilot signal is 5 considered detected.
- the audio for the entire hop is then multiplied by the reciprocal of the peak value (i.e. gain ⁇ constant/peak). This is known as "hop by hop AGC” .
- the audio following the pilot signal is then expanded (or uncompressed) in time by the same percentage that it was originally compressed. The uncompressed received audio is illustrated at the bottom of Figure 2.
- the digital signal processor illustrated in Figure 1 implements seamless frequency hopping in the m - time domain by using standard digital signal processing techniques for interpolation and decimation to accomplish the audio time compression.
- the transmit algorithm for frequency hopping is illustrated in Figure 3. As an example of its 0 operating characteristics we will assume that there are 2,000 samples per hop and a 90% compression ratio.
- the input line 31 carries 2,000 samples of audio input collected as a lot. This lot enters a 1:9 resampler where the lot is
- Mux 35 is sequenced at each hop to allow 100 mute samples (zeros) to pass at the beginning of a hop (indicated by change frequency strobe 17 of Figure 1), followed by 100 samples from the pilot signal generator 36, followed by the 1,800 samples of compressed audio.
- mute samples zeros
- the pilot signal generator 36 the pilot signal generator 36
- 1,800 samples the 1,800 samples of compressed audio.
- 2,000 audio samples are collected from audio input interface circuitry (13 of Figure 1) for processing and 2,000 samples are sent on to audio output interface circuitry (21 of Figure 1) after processing.
- Figure 5 illustrates a receive algorithm for seamless frequency hopping.
- a sampled audio input enters on input line 41 and is split between a correlator 42, a multiplexor 43 and a 1:10 resampler 44.
- the correlator correlates the received audio with a stored replica of the pilot signal and detects the time and amplitude of the peak. This information is passed on to Controller 45.
- the controller uses this information to control the Mux Select Line 46, to set the gain line 47 for amplifier 48, and to assert the Begin Sampling Strobe 49 that enables the 1:10 resampler to begin collecting samples.
- the 1:10 resampler does not begin collecting samples until this line is asserted.
- the controller asserts this line at the time the peak is detected by the correlator. This occurs when the correlator detects the pilot signal and thus provides accurate synchronization on a hop by hop basis.
- the resampler will not begin collecting samples until after approximately 200 samples have already been collected.
- the next 1,800 samples are then padded with zeros to a 10:1 ratio bringing the total number of samples in the lot to 18,000.
- the resampled lot then flows through low pass filter 50 and enters 9:1 resampler 51 where the filtered lot is resampled at a 9:1 ratio (i.e.
- Every ninth sample is selected and the others are discarded) bringing the lot size down to 2,000 samples.
- These 2,000 samples then enter amplifier 48 which also receives gain signal 47 from Controller 45.
- the amplified output then enters logarithmic limiter 52 which reduces the peak signal output to a value that is below the maximum allowable D/A converter value.
- the output from the logarithmic limiter enters both multiplexor 43 and one hop delay line 53.
- the one hop delay line in this embodiment is a 2,000 sample delay line which, in essence, presents the output from the last hop to multiplexor 43.
- Controller 45 via Mux Select Line 46 selects which multiplexor input is passed through the multiplexor and out of the system.
- the controller selects which signal to output based on the peak amplitude it receives from correlator 42.
- the controller integrates this value to determine if a pilot signal is being sent on a consistent basis. If not, the controller effectively bypasses the seamless frequency hop processing by passing line 41 to the multiplexor output. If the pilot signal is being consistently sent and the current hop's peak amplitude exceeds a detection threshold, then line 54 is passed through to the multiplexor output. If the pilot signal is being consistently sent but the current hop's peak amplitude does not exceed the detection threshold, then the samples from the last hop (line 55) are passed to the multiplexor output enabling the repetitive squelch. Audio output exits multiplexor 43 on audio output line 56 and the output data is sent to audio output interface circuitry (21 of Figure 1) .
- stopband frequency sampling frequency * compression ratio /2
- the pilot signal that is transmitted with the compressed audio could be a single frequency sinusoid, a chirped sinusoid (a sinusoid whose frequency changes linearly with time) or a digitally coded waveform.
- the critical point is that a replica of the pilot signal be stored in the correlator at the receiver (If the waveform is complex, the conjugate of the pilot signal must be stored in the correlator).
- the pilot signal is a sinusoid whose frequency is linearly increased in time from 0.0625 times the sampling frequency (500 Hz.) to 0.375 times the sampling frequency (3 KHz.) over the space of 100 samples (12.5 msec).
- the software implementation of the frequency hopping processor here described collects the samples in small lots and then processes them as such.
- the processes of audio time compression and expansion that are accomplished with zero stuff / low pass filter / re-sample stages are integrated and implemented as two individual routines (expand and compress) . It is important to note that during the process of resampling, most of the audio samples are 5 discarded. In a preferred embodiment, these discarded samples would not be calculated in the first place in order to reduce throughput loading in the digital signal processor.
- the seamless frequency hopping system of the 0 present invention can be utilized in any frequency hopping communication scheme. It is not intended that this invention be limited to the hardware or software arrangement, or operational procedures shown disclosed. This invention includes all of the 5 alterations and variations thereto as encompassed within the scope of the claims as follows.
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- Engineering & Computer Science (AREA)
- Computer Networks & Wireless Communication (AREA)
- Signal Processing (AREA)
- Reduction Or Emphasis Of Bandwidth Of Signals (AREA)
Abstract
A seamless frequency hopping system utilizes a programmable digital signal processor with interface circuitry in conjuction with a frequency hopping radio to incorporate the concepts of audio time compression, hop by hop automatic gain control and time repeating squelch to improve the sound of frequency hopped analog communication. Incoming uncompressed audio is first sliced into time segments that each correspond to one frequency hop. The uncompressed audio is then compressed to a certain percentage of its original length in time. A dead time as well as a pilot signal is added to the front of the audio. The processed audio signal is then sent to the radio where it is modulated and broadcast. A second radio receives the incoming signal and demodulates it to once again become an audio signal.
Description
SEA LESS FREQUENCY HOPPING SYSTEM
Background of the Invention
Field of the Invention
The present invention is related to 0 communication systems and more specifically to reducing interference while communicating by utilizing frequency hopping.
Description of the Prior Act -, c In any electronic communication system there is a certain amount of interference which must be controlled. This interference can be any electrical or electromagnetic disturbance, phenomena, signal, or emission, man-made or natural, which causes or can
20 cause an undesired response, malfunctioning, or degradation of the electrical performance of electrical equipment. To reduce or eliminate this interference or jamming there are several prior art techniques. One such prior art technique is to
25 utilize frequency hopping.
Several problems are associated with frequency hopping, however. First, the audio signal is chopped with a dead time that occurs at the beginning of each hop. Second, the signal strength varies from hop to
30 hop. Finally, certain channels are already occupied with a strong signal that can drown out the hopping signal. These three phenomena are known as hop noise and can be very distracting.
35
It is an object of the present invention to avoid the deficiencies of typical frequency hopping as well as the deficiencies of other prior art noise elimination techniques and to provide an improved 5" communication system in which the operator will not notice a change in the audio output from single frequency operation to frequency hopping operations.
Summary of the Invention
10
In accordance with the present invention a seamless frequency hopping system is provided which incorporates the concepts of audio time compression, hop by hop automatic gain control and time repeating je squelch to improve the sound of frequency hopped analog communication. The system is implemented by utilizing a digital signal processor with its associated electronics in conjunction with a frequency hopping radio.
20 grief Description of the Drawings
Figure 1 illustrates a hardware block diagram of the present invention, m m Figure 2 illustrates frequency hopping audio time compression.
Figure 3 illustrates a transmit algorithm for frequency hopping.
Figure 4 illustrates the contents of a transmit 30 hop frame after processing.
Figure 5 illustrates a receive algorithm for frequency hopping.
Figure 6 illustrates magnitude response of an ideal interpolation low pass filter.
35
Detailed Description of the Invention
In accordance with the present invention a seamless frequency hopping system is provided which 5 utilizes a digital signal processor (DSP) that time compresses voice during a single frequency dwell and then expands it to completely fill the dwell time including the hop dead time. By utilizing various algorithms, the effect is no change in the audio lø output from single frequency operation to frequency hopping operations. Therefore, the hopping operation is nearly transparent to the radio operator/pilot and the operator does not hear the annoying repetition- rate clicks associated with a typical hopping ic operation.
Turning now to Figure 1 of the drawings, we have a hardware block diagram of the seamless frequency hopping system of the present invention. The main component of the hardware of the seamless frequency
20 hopping system is the programmable digital signal processor (DSP) 11. Also shown in Figure 1 is memory
12 and input interface circuitry 13. As can be seen from Figure 1 a single analog input, from a frequency hopping radio 10, enters on input line 14 into input interface circuitry 13. Input interface circuitry 13
25 can be an ATT 7522 codec or any similar device having an analog to digital converter and an anti-aliasing filter. In this example, input interface circuitry
13 has a sample rate of approximately 8KHZ. From
30 input interface circuitry 13 the signal follows, in a serial manner, line 15 which connects input interface circuitry 13 with digital signal processor 11. Digital signal processor 11 which may be an ATT DSP32C or any similar device, interfaces to a
.,-. frequency hopping radio 10 through a transmit receive line 16 and a change frequency strobe line 17. Digital
signal processor 11 also interfaces with memory 12 through address line 18 and data line 19 in a manner which is known by one skilled in the art. Digital signal processor 11 with memory 12 performs software 5 processing as discussed below. Memory 12 in this example is a 4Kx32 EEPROM, but may be any similar storage device. After software processing, an output from digital signal processor 11 follows, in a serial manner, output line 20. Output line 20 connects !Q digital signal processor 11 with output interface circuitry 21. Output interface circuitry 21 can be an AT&T 7522 codec or any similar device having a digital to analog converter and an anti-aliasing filter. After output interface circuitry 21, the -, processed signal flows out of the seamless frequency hopping system on analog output line 22 to a frequency hopping radio 10. The system will sense when the radio is transmitting via transmit/ receive line 16. When transmitting, the system receives audio from the radio microphone port via input line
20 14 and outputs audio to the radio transmitter via output line 22. When receiving, the system receives audio in from the radio receiver via input line 14 and outputs audio to the radio audio amplifier via output line 22. The multiplexing of these analog 5 lines is handled external to the system by the radio.
The concepts of seamless frequency hopping are illustrated in Figure 2. At the top of Figure 2, incoming uncompressed audio is first sliced into time 30 segments that each correspond to one frequency hop. The uncompressed audio is then compressed to a certain percentage of its original length in time. A dead time as well as a pilot signal are added to the front of the audio. The pilot signal is used for 5 synchronization, automatic gain control (AGC) , squelch and algorithm activation. The processed
audio signal is then sent to the radio where it is modulated and broadcast.
A second radio receives the incoming signal and demodulates it to once again become an audio signal. 5 The received audio is first passed through a correlator to detect the pilot signal that was inserted at the front of the hopped audio. The peak output from the correlator is used to set the gain control and the squelch for the entire hop. If that o output is too low, then the pilot signal wasn't detected and the audio signal from the previous hop is replicated for this hop. This process is known as "repetitive squelch". If the correlator peak output passes a certain threshold, then the pilot signal is 5 considered detected. The audio for the entire hop is then multiplied by the reciprocal of the peak value (i.e. gain ■ constant/peak). This is known as "hop by hop AGC" . The audio following the pilot signal is then expanded (or uncompressed) in time by the same percentage that it was originally compressed. The uncompressed received audio is illustrated at the bottom of Figure 2.
The digital signal processor illustrated in Figure 1 implements seamless frequency hopping in the m - time domain by using standard digital signal processing techniques for interpolation and decimation to accomplish the audio time compression. The transmit algorithm for frequency hopping is illustrated in Figure 3. As an example of its 0 operating characteristics we will assume that there are 2,000 samples per hop and a 90% compression ratio. In this embodiment, the input line 31 carries 2,000 samples of audio input collected as a lot. This lot enters a 1:9 resampler where the lot is
35 padded with zeros to a 9:1 ratio bringing the total number of samples in the lot to 18,000. The resampled lot then flows through low pass filter 33
and enters 10:1 resampler 34 where the filtered lot is resampled at a 10:1 ratio (i.e. every tenth sample is selected and the others are discarded) . This brings the lot size down to 1,800 samples. These compressed audio samples then enter mux 35 which also receives a signal from pilot signal generator 36 and mute signal generator 37. Audio output exits mux 35 on output line 38. Mux 35 is sequenced at each hop to allow 100 mute samples (zeros) to pass at the beginning of a hop (indicated by change frequency strobe 17 of Figure 1), followed by 100 samples from the pilot signal generator 36, followed by the 1,800 samples of compressed audio. Thus, 2,000 audio samples are collected from audio input interface circuitry (13 of Figure 1) for processing and 2,000 samples are sent on to audio output interface circuitry (21 of Figure 1) after processing.
The contents of the transmit hop frame after processing are illustrated in Figure 4. At start of hop 25 there exists 100 samples of zeros (dead time) 26 followed by 100 samples of pilot signal 27 followed by 1800 samples of compressed audio 28 followed by end of hop 29.
Figure 5 illustrates a receive algorithm for seamless frequency hopping. Once again, assuming that there are 2,000 samples per hop and a 90% compression ratio the following will illustrate the operating characteristics of the receive algorithm. A sampled audio input enters on input line 41 and is split between a correlator 42, a multiplexor 43 and a 1:10 resampler 44. The correlator correlates the received audio with a stored replica of the pilot signal and detects the time and amplitude of the peak. This information is passed on to Controller 45. The controller uses this information to control the Mux Select Line 46, to set the gain line 47 for amplifier 48, and to assert the Begin Sampling Strobe
49 that enables the 1:10 resampler to begin collecting samples. The 1:10 resampler does not begin collecting samples until this line is asserted. The controller asserts this line at the time the peak is detected by the correlator. This occurs when the correlator detects the pilot signal and thus provides accurate synchronization on a hop by hop basis. Thus, the resampler will not begin collecting samples until after approximately 200 samples have already been collected. The next 1,800 samples are then padded with zeros to a 10:1 ratio bringing the total number of samples in the lot to 18,000. The resampled lot then flows through low pass filter 50 and enters 9:1 resampler 51 where the filtered lot is resampled at a 9:1 ratio (i.e. every ninth sample is selected and the others are discarded) bringing the lot size down to 2,000 samples. These 2,000 samples then enter amplifier 48 which also receives gain signal 47 from Controller 45. The amplified output then enters logarithmic limiter 52 which reduces the peak signal output to a value that is below the maximum allowable D/A converter value. The output from the logarithmic limiter enters both multiplexor 43 and one hop delay line 53. The one hop delay line in this embodiment is a 2,000 sample delay line which, in essence, presents the output from the last hop to multiplexor 43. Controller 45 via Mux Select Line 46 selects which multiplexor input is passed through the multiplexor and out of the system. The controller selects which signal to output based on the peak amplitude it receives from correlator 42. The controller integrates this value to determine if a pilot signal is being sent on a consistent basis. If not, the controller effectively bypasses the seamless frequency hop processing by passing line 41 to the multiplexor output. If the pilot signal is being
consistently sent and the current hop's peak amplitude exceeds a detection threshold, then line 54 is passed through to the multiplexor output. If the pilot signal is being consistently sent but the current hop's peak amplitude does not exceed the detection threshold, then the samples from the last hop (line 55) are passed to the multiplexor output enabling the repetitive squelch. Audio output exits multiplexor 43 on audio output line 56 and the output data is sent to audio output interface circuitry (21 of Figure 1) .
The low pass filters in both the receive and transmit channels require the stopband frequency to be less than 0.45 times the original sampling frequency (the general case is: stopband frequency = sampling frequency * compression ratio /2) . The closer the frequency response to the ideal filter shown in Figure 6, the better the performance of the system.
The pilot signal that is transmitted with the compressed audio could be a single frequency sinusoid, a chirped sinusoid (a sinusoid whose frequency changes linearly with time) or a digitally coded waveform. The critical point is that a replica of the pilot signal be stored in the correlator at the receiver (If the waveform is complex, the conjugate of the pilot signal must be stored in the correlator). In this embodiment, the pilot signal is a sinusoid whose frequency is linearly increased in time from 0.0625 times the sampling frequency (500 Hz.) to 0.375 times the sampling frequency (3 KHz.) over the space of 100 samples (12.5 msec).
The software implementation of the frequency hopping processor here described collects the samples in small lots and then processes them as such. The processes of audio time compression and expansion that are accomplished with zero stuff / low pass
filter / re-sample stages are integrated and implemented as two individual routines (expand and compress) . It is important to note that during the process of resampling, most of the audio samples are 5 discarded. In a preferred embodiment, these discarded samples would not be calculated in the first place in order to reduce throughput loading in the digital signal processor.
The seamless frequency hopping system of the 0 present invention can be utilized in any frequency hopping communication scheme. It is not intended that this invention be limited to the hardware or software arrangement, or operational procedures shown disclosed. This invention includes all of the 5 alterations and variations thereto as encompassed within the scope of the claims as follows.
G
5
0
5
Claims
1. A seamless frequency hopping system comprising: a radio; audio time compression means; 10 hop by hop automatic gain control means; and time repeating squelch means to improve sound of frequency hopped analog communication.
2. A seamless frequency hopping system comprising: 15 a radio; input interface circuitry means for receiving an analog input from said radio and for providing a digitized signal; digital signal processor means connected to - - said radio and said input interface circuitry means for performing processing of said digitized signal and for providing a processed signal; memory means connected to said digital signal processor means for providing storage for said m m digital signal processor means; output interface circuitry means connected to- said digital signal processor means and connected to said radio for receiving said processed signal from said digital signal processor means and for 30 providing an output signal to said radio.
3. A seamless frequency hopping system as claimed in claim 2 wherein said digital signal processor means is connected to said radio via transmit/ 35 receive line and a change frequency strobe line.
4. A seamless frequency hopping system as claimed in claim 2 wherein said input interface circuitry means is an ATT 7522 codec or any similar device.
5. A seamless frequency hopping system as claimed in claim 2 wherein said input interface circuitry means comprises: analog to digital converter means; and, anti-aliasing filter means.
6. A seamless frequency hopping system as claimed in claim 2 wherein said input interface circuitry means has a sample rate of 8KHZ.
7. A seamless frequency hopping system as claimed in claim 2 wherein said digital signal processor means is an ATT DSP 32 C or any similar device.
8. A seamless frequency hopping system as claimed in claim 2 wherein said memory means is a 4Kx32 EEPROM or any similar device.
9. A seamless frequency hopping system as claimed in claim 2 wherein said output interface circuitry means is an ATT 7522 codec or any similar device.
10. A seamless frequency hopping system as claimed in claim 2 wherein said output interface circuitry means comprises: digital to analog converter means; and, anti-aliasing filter means.
11. A method for performing seamless frequency hopping comprising the steps of: receiving incoming uncompressed audio; slicing said incoming uncompressed audio into time segments that each correspond to one frequency hop therefore providing sliced uncompressed audio; compressing said sliced uncompressed audio to a percentage of its original length in time therefore providing sliced compressed audio; adding a dead time and a pilot signal to' said sliced compressed audio therefore providing processed audio; transmitting said processed audio to a radio where it is modulated and broadcast.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US62480590A | 1990-12-05 | 1990-12-05 | |
US624,805 | 1990-12-05 |
Publications (1)
Publication Number | Publication Date |
---|---|
WO1992010882A1 true WO1992010882A1 (en) | 1992-06-25 |
Family
ID=24503380
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/US1991/006347 WO1992010882A1 (en) | 1990-12-05 | 1991-09-05 | Seamless frequency hopping system |
Country Status (2)
Country | Link |
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AU (1) | AU9123791A (en) |
WO (1) | WO1992010882A1 (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO1995030288A1 (en) * | 1994-04-28 | 1995-11-09 | Linkplus Corporation | Frequency synchronization for frequency hopping communication using calibration tone sent at hop |
US5907925A (en) * | 1996-12-09 | 1999-06-01 | Guyot; Jean Noel | Method for treatment of waste material |
Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE2061744A1 (en) * | 1969-12-23 | 1971-07-01 | Philips Nv | Device for transmitting information when the frequency changes |
EP0068690A1 (en) * | 1981-06-22 | 1983-01-05 | The Marconi Company Limited | Radio communications receivers |
ZA84374B (en) * | 1983-01-20 | 1984-08-29 | Grinaker Electr Holdings Pty L | Radio communication equipment |
DE2706615C1 (en) * | 1977-02-17 | 1990-11-15 | Siemens Ag | Radio system |
DE3447548C1 (en) * | 1984-12-28 | 1990-12-20 | Siemens Ag | Radio transmission method for tactical use - using frequency pumps to transmit information in bursts and returning synthesisers |
-
1991
- 1991-09-05 WO PCT/US1991/006347 patent/WO1992010882A1/en active Application Filing
- 1991-09-05 AU AU91237/91A patent/AU9123791A/en not_active Abandoned
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE2061744A1 (en) * | 1969-12-23 | 1971-07-01 | Philips Nv | Device for transmitting information when the frequency changes |
DE2706615C1 (en) * | 1977-02-17 | 1990-11-15 | Siemens Ag | Radio system |
EP0068690A1 (en) * | 1981-06-22 | 1983-01-05 | The Marconi Company Limited | Radio communications receivers |
ZA84374B (en) * | 1983-01-20 | 1984-08-29 | Grinaker Electr Holdings Pty L | Radio communication equipment |
DE3447548C1 (en) * | 1984-12-28 | 1990-12-20 | Siemens Ag | Radio transmission method for tactical use - using frequency pumps to transmit information in bursts and returning synthesisers |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO1995030288A1 (en) * | 1994-04-28 | 1995-11-09 | Linkplus Corporation | Frequency synchronization for frequency hopping communication using calibration tone sent at hop |
US5907925A (en) * | 1996-12-09 | 1999-06-01 | Guyot; Jean Noel | Method for treatment of waste material |
Also Published As
Publication number | Publication date |
---|---|
AU9123791A (en) | 1992-07-08 |
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