The present invention relates to signaling systems, and more particularly, to a narrowband antijam (AJ) signal system.
The Global Positioning system and other Global Navigation Satellites Systems (GNSS) transmit direct sequence spread spectrum (DSSS) signals that provide time of arrival and related information needed to compute ranging solutions. These signals have some inherent resistance to jamming that improves with the greater spread bandwidth of the signal. In the GPS, authorized signals have been designed to have wider bandwidths than their counterpart civilian signals so that the authorized signals have greater resistance to jamming. Jam resistant communication systems also use some of the same wide bandwidth spread spectrum signaling techniques, such as DSSS and frequency hopped spread spectrum (FHSS), to achieve greater resistance to jamming. Optionally, these systems may use other spread spectrum techniques known in the art to achieve greater resistance to jamming.
The reason for this is that according to conventional wisdom, spread spectrum communication and navigation systems are limited in their inherent AJ performance by spreading gain, which is proportional to the effective signal bandwidth. For example, the encrypted M and P(Y) code GPS signal occupies over 10 times the effective bandwidth of the civilian C/A code GPS signal, making C/A code inherently 10 times less resilient to jamming as P(Y) or M codes. See, for example, “Capt. Brian C. Barker, et., al, Overview of the GPS M code signal,” Proceedings of the National Technical Meeting, January 2000 for illustration of the M code and P(Y) (also referred to as Y code) bandwidths relative to the C/A code signal's bandwidth. In another example, protected tactical communication also employs frequency hopping over very wide bandwidths to provide more inherent resistance to jamming than narrowband systems.
Wider bandwidth systems, however, are limited by available spectrum and the dynamic range of components. For example, wide-bandwidth analog-to-digital converters (ADCs) typically have much lower precision, effective number of bits (ENOB), than narrowband ADCs. Because of these limitations, the maximum tolerable jammer-to-signal (J/S) power ratio is limited by ADC precision and the achievable dynamic range of radio frequency components.
Moreover, the signal acquisition time in wideband GPS receivers, such as M code and P(Y) code receivers, is much longer than that of civilian GPS signals, such as the civilian course acquisition (C/A) code signal, because the signals do not repeat. For this reason, searching for the correct code phase in a reasonable time requires much more complex acquisition search engines. For example, the Time to First Fix (TTFF) of the wideband P(Y) and M code signals can be (>>60 seconds), which is much longer than in receivers designed for mass market consumer applications using the C/A code signal or other civilian GPS or GNSS signals. In general, the TTFF for civilian GNSS signals is typically much smaller than the TTFF of wideband signals designed for jam resistance.
Thus, alternative jam resistant signaling systems are needed, which may improve resistance to jamming, do not require additional spectrum, and reduce TTFF without relying on signal repetition used in the C/A code or other civilian GNSS signals such as L1C, L2C and GNSS signals from systems other than GPS.
Certain embodiments of the present invention may provide solutions to the problems and needs in the art that have not yet been fully identified, appreciated, or solved by current wideband AJ signaling systems. For example, some embodiments may pertain to NASS, which uses lower rate signals and exploits a wide dynamic range radio frequency (RF) front end and high precision ADC technology.
In an embodiment, a narrowband AJ signaling system includes an AJ processor placed between a high precision analog-to-digital (ADC) converter and a narrowband digital receiver. In some other embodiments, the AJ processor is placed between the high precision ADC and a digital-to-analog converter (DAC). The AJ processor of either embodiment may suppress the jammer power down to a level based on the noise floor of the system.
In another embodiment, optimal longer coherent integration times are selected with NASS receivers to achieve improved Time to First Acquisition (TTFA) under jamming relative to wideband signal systems, even in the absence of AJ processing.
In order that the advantages of certain embodiments of the invention will be readily understood, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments that are illustrated in the appended drawings. While it should be understood that these drawings depict only typical embodiments of the invention and are not therefore to be considered to be limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings:
Some embodiments generally pertain to a narrowband AJ signaling system that includes an AJ processor placed between a high precision ADC converter and a narrowband digital receiver. In some other embodiments, the AJ processor is placed between the high precision ADC and a DAC. The AJ processor of either embodiment may suppress the jammer power down to the level of the noise floor of the system or any other appropriate level.
The integrated narrowband signaling system 100 includes a wide dynamic range RF front end and automatic gain control (AGC) module 102, a high precision ADC 104, AJ processor 106, and a narrowband digital receiver signal processor 108. In some embodiments, wide dynamic range RF front end and AGC module 102 includes a low noise amplifier (not shown) that amplifies RF signals, a band pass filter (not shown) that filters out unwanted RF spectrum, a RF downconverter (not shown) that downconverts RF signals to an intermediate frequency (IF) and an anti-aliasing filter (not shown) that filters out unwanted RF signals before the signals are digitized by the high precision ADC. Depending on the specific design, filters may also be employed in the wide dynamic range front end and AGC module 102. In some embodiments, the AGC module may also be omitted.
In other embodiments, the RF downconverter may be a quadrature downconverter that downconverts the in-phase (I) and quadrature (Q) channel signals, followed by an optional anti-aliasing filter that removes higher frequency components before digitization by high precision ADC 104. In some other embodiments, high precision ADC 104 may include two channels, one for digitizing one or more I channel signals and one for digitizing one or more Q channel signals. In some further embodiments, multiple RF front end and AGCs may be used in combination to receive signals from different antennas, as would be the case for a multi-element antenna receiver configuration. Many variations of the RF front end and AGC module 102 may also be employed such as a multi-stage RF front end employing one or more amplifiers, one or more mixers, one or more AGCs and one or more filters.
Thereafter, high precision ADC 104 provides 18 bits or more of precision and may provide 16 or more ENOB. High precision ADC 104 may include one channel for digitization at an IF or two channels for digitization of I and Q signals at baseband. In another embodiment, high precision ADC 104 contain more than two channels dependent on the number of RF front end and AGC stages.
Conventionally, military GPS navigation signals, such as the encrypted M-code and P(Y) code signals, typically offer 10 dB greater AJ performance than the repeating civilian C/A code civilian signal. This is since military GPS navigation signals typically have at least 10 times the bandwidth. In some embodiments, P(Y) and M-code receivers and AJ processors described herein constitute components of a wideband AJ signaling system. For example, in some embodiments, AJ processor 106 is integrated with the receiver electronics in a single unit as in the case of
Regardless of the embodiment, AJ processor 106 may suppress the jammer power down to the level of the noise floor of the system. This suppression is typically achieved in one or more domains (e.g., time, frequency, amplitude, or spatial domains). Alternatively, other domains may also be used such as the wavelet transform domain. These techniques may include frequency domain excision, time domain excision, spatial nulling and/or beamforming using multi-element antennas or amplitude domain techniques. See, for example, U.S. Pat. Nos. 9,391,654 B2, 9,654,158 B2 and 9,923,598 B2.
After the signal is passed through wideband front end 102 and is digitalized using a high precision ADC 104, AJ processor 106 may operate on the signal to suppress the interference prior to further processing of the signal by narrowband digital receiver processor 108. In some embodiments, narrowband digital receiver 108 acquires the narrowband signal, performs code and carrier tracking, and demodulates data from the signal. In other embodiments, narrowband digital receiver signal processor 108 may also include circuitry (not shown) configured to convert the bit resolution from high precision (18 or more bits) to low precision (fewer than 18 bits) optimally reducing power consumption in the narrowband digital receiver signal processor 108. For example, when narrowband digital receiver signal processor 108 processes a GNSS navigation signal, narrowband digital receiver signal processor 108 uses between 1-6 bits to conserve power. This may be achieved by truncating or thresholding the high-resolution bit stream to convert the stream to a low resolution bit stream, for example.
The signal acquisition may utilize active parallel correlator or passive matched filter implementations. See, for example, P. A. Dafesh and J. K. Holmes, “Practical and Theoretical Tradeoffs of Active Parallel Correlator and Passive Matched Filter Acquisition Implementations”, Proceedings of the IAIN World Congress and the 56th Annual Meeting of The Institute of Navigation, 2000.
In some embodiments, navigation data is obtained from the narrowband signal directly prior to the receiver computing a position fix. In other embodiments, navigation data is obtained over an alternative communication channel using assisted GPS techniques. The data may be conventional navigation data or may be long term orbital and clock information that enables the receiver to obtain a navigation fix over a period of up to 7 days or longer. In some embodiments, the receiver is a digital GPS navigation receiver. In other embodiments, the receiver is a digital GNSS navigation receiver. As such, the receiver computes its own position using satellite-based positioning techniques. The receiver may also compute pseudorange, pseudorange rate, and/or carrier phase measurements, which may also be used to compute a receiver's position along with other information such velocity and time information. This position computation may alternatively be performed in a server or on a cloud computer. In other embodiments, the receiver may be a communication receiver that demodulates data messages from a modulated narrowband signal.
Wide dynamic range RF front end and automatic gain control module 204, high precision ADC 206, and AJ processor 208 of
Within narrowband signal receiver 214, RF front end 216 may be configured for application to GPS signal reception or communication signal reception as is the case for the RF front end 102 of
In this embodiment, ADC 218 may be a single or multi-channel ADC depending in whether it is digitizing an IF signal or I and Q signals at baseband. Since the jammer power is mostly suppressed by AJ processor 208, the required precision for ADC 218 may be reduced. Therefore, depending on the embodiment, ADC 218 may be a high precision ADC (≥18 bits) or a low precision (<<14 bits) ADC.
High precision ADC 206 used in some embodiments exploits ADCs having 18 to 24 or greater bits of resolution. This is distinguished from ADC converters used in C/A code civilian receivers that are traditionally low precision (<<14 bits) ADCs to save power and cost for mass market consumer applications. Further, the C/A code signal is unencrypted making the C/A code signal subject to spoofing attacks, further distinguishing C/A code receiver systems from the embodiments described herein.
High precision ADC 206 (having 18 or greater bits) may operate on a narrowband encrypted military signal having an occupied spectrum that is ≤ 1/10th of the M and P(Y) code spectrum. One exemplary narrowband signal is an encrypted pseudorandom noise code (PRN) signal that is chipped at 0.5115 Mchips/sec and centered at 10.23 MHz away from the L1 GPS carrier frequency located at 1575.42 MHz. Another example is a binary offset carrier (BOC) modulated signal that is constructed as the product of a 10.23 MHz sine or cosine phase square-wave subcarrier multiplied by a 0.5115 million chips per second (MCPS) spreading code. The nomenclature for BOC signals in GNSS systems is usually denoted by BOC(M,N), where M is the subcarrier frequency divided by 1.023×106 and N is the code chipping rate divided by 1.023×106. This signal may be denoted as BOC(10,0.5). While the BOC (10,0.5) signal is considered narrowband relative to the BOC(10,5) M code signal, it should be clear that other narrowband signals may also be used in conjunction with a NASS receiver. In this example, the signal is centered on either L1 and/or L2 GPS frequencies at 1575.42 MHz and/or 1227.60 MHz, respectively. The signal may be centered on other carrier frequencies as well. In the second example, the chip rate of the signal is 1/10th of the chip rate of the M code signal, and therefore, the signal occupies about 1/10th of the spectrum. This may be considered narrowband for the purpose of describing exemplary embodiments of the invention.
Other narrowband signals, relative to the wideband GPS M code or P(Y) code encrypted signals, may include any spread spectrum signal that are ≤ 1/10th of the M and P(Y) code spectrum. For example, a BPSK 0.1 MCPS signal would meet this definition relative to the 10 MCPS Y code signal. In another example, a BOC(10,0.25) signal would also meet this definition. The spectrum of the BOC(10,5) M code and BOC(10,0.5) narrowband signal are shown in
In the BOC example, the upper and/or lower sidebands of the BOC signals are rotated to band center in a NASS receiver by using an analog downconverter. This may be achieved using existing hardware by offsetting the downconverter's local oscillator by +10.23 MHz or −10.23 MHz for upper and lower sidebands, respectively. For example, a NASS receiver that receives the BOC(10,0.5) signal may employ a number of approaches to sample the received signal using a high-precision narrowband ADC.
Referring to
In another embodiment, both sidebands may be processed at once. In such an embodiment, wide dynamic range RF front end and ADC 102 may downconvert the upper sideband and upconvert the lower sideband to produce downconverted upper and lower sidebands, Both the upper and lower sideband signals would each be processed by a separate AJ processor, one for the lower sideband signal and one for the upper sideband signal. Alternatively, both the upper sideband signal and the lower sideband signal would be received by the narrowband signal receiver.
In some embodiments, narrowband digital receiver signal processor 108 may perform joint processing of both upper and lower sidebands after AJ processor 106, while in other embodiments, the narrowband digital receiver signal processor 108 may separately process upper and lower sidebands and combine the results non-coherently. Other variations may also be employed such as time multiplexing the processing on either sideband.
A dual channel wide dynamic range RF front end and AGC capable of processing in this manner shown in
Also, in this embodiment, dual channel wide dynamic range RF front end and AGC 402 includes dual quadrature downconversions (QDCs) 408 and 410. QDC 408 downconverts the 0.5115 MCPS spreading codes at the upper sideband (USB) frequency of 10.23 MHz above the carrier, and QDC 410 downconverts the 0.5115 MCPS spreading codes at the lower sideband (LSB) frequency of 10.23 MHz below the carrier to baseband (I/Q) or approximately zero Hz.
As illustrated by
Alternatively, two single channel ADCs may be used to digitize I and Q components of the USB BPSK 0.5115 MCS PRN code with an additional two single high-precision ADCs used to digitize the I and Q components of the LSB BPSK 0.5115 MCPS PRN code. Other embodiments may employ a quad channel high precision ADC. In this example, a suitable sampling rate may be chosen between 1-1.5 MSamp/sec, depending on the bandwidth of the anti-aliasing low pass filters in
It should be appreciated that variations of this embodiment can also be performed in which the USB and LSB signal components are downconverted to an IF frequency and digitized using two single channel high precision ADCs (one for LSB and one for USB signal components). This may be followed by digital downconversion of the digital IF signal to baseband I and Q components prior to USB AJ processor 416 and LSB AJ processor 418.
In an exemplary embodiment, a signal is considered narrowband relative to a wideband system if it its spreading modulation occupies ≤ 1/10th the null-to-null bandwidth of spreading modulation used in a complementary wide bandwidth signaling system. In the case of direct sequence spread spectrum systems, this corresponds to having a chipping rate that is ≤ 1/10th that of the corresponding wideband system's chip rate. A narrowband system may be used in conjunction with a wideband signaling system as an augmentation to the wideband system or as an alternative to a wideband system.
It should be understood that variations of the NASS system may employ a narrowband DSSS signal that is optionally hopped over a wide bandwidth by regularly changing the center frequency of the DSSS PRN code signal, but having a chip rate that is ≤ 1/10th that of the corresponding wideband system's chip rate.
In the embodiments shown in
Note that, in alternative embodiments, wideband signaling receivers for M code, P(Y) code or other global navigation satellite signal (GNSS) receivers may produce a multi-mode receiver that operates as NASS signals to reduce power consumption and provide enhanced AJ processing. The wideband signaling receivers may also operate on conventional signals, for example, to demodulate navigation data from such systems or to optimize overall navigation performance dependent on the environmental conditions or receiver operating scenarios.
The achievable performance of AJ techniques is ultimately limited by the dynamic range of the system. In general, the tolerable J/S is related to the difference between the MSB of the ADC and the noise level. For example, if 85 dB of J/S is achievable with a 12-bit ADC, an additional 54 dB of jammer suppression would be realizable with a 21-bit ADC due to increased quantization range which increases as about 6.02 dB per bit. Therefore, the net improvement of a 10× lower signaling rate would be equal to 54 dB-10 dB (loss in processing gain). This results in approximately 44 dB or a factor of 25119 improvement in tolerable jammer power, or tolerable J/S for the same signal power level, for a NASS (combining both AJ processing and a narrowband AJ signal system (NASS) receiver's AJ performance), as compared to wideband signaling receivers This may also result in improved AJ performance for the narrowband system which is contrary to conventional wisdom in which a wideband AJ system is expected to result in greater resistance to jamming than a narrowband AJ system.
In an embodiment, multi-mode receiver 700 processes a narrowband BOC(10,0.5) signal in a number of different ways. In one example, USB quadrature RF downconverters 706-1 and 706-3 are respectively configured to downconvert an USB and a LSB of the BOC(10,0.5) signal using conventional means previously applied to the BOC(10,5) signal and related modulation. More details regarding the downconverting process can be found in P. A. Dafesh and J. K. Holmes, “Practical and Theoretical Tradeoffs of Active Parallel Correlator and Passive Matched Filter Acquisition Implementations”, Proceedings of the IAIN World Congress and the 56th Annual Meeting of The Institute of Navigation, 2000 or in the discussion of
As shown in
Further, because the signal is sampled with high-resolution ADC 708-1 and 708-3, the ability to resolve the jammer's power (J) relative to the noise floor is greatly enhanced, thereby increasing the maximum jammer that may be tolerated. For example, the 24-bit ADC enables more than a 30 dB improvement in dynamic range (tolerable jammer power), compared to a 12-bit ADC typical of wide-bandwidth AJ systems in which chipping rate of the PRN code is at least 10 times greater.
In this embodiment, AJ processors 710-1 and 710-3 are configured to suppress the effect of the jammer signal. For example, a narrowband jammer that jams a portion of the USB and LSB spectrum of the BOC(10,0.5) signal, for example, by notching out 10% of the upper and lower sideband power spectrum (e.g., see graph 300B in
After AJ processor, the bit depth of the signal plus noise is reduced using a thresholding circuit. In some embodiments, the bit depth is reduced to 2 bits to enable the subsequent acquisition and tracking circuits to conserve power by reducing the number of operations per second for more efficient power operations. Generally, the number of operations per second scales with the bit resolution.
In other embodiments, multi-mode NASS receiver 700 also concurrently tracks wide-bandwidth signals, such as the BOC(10,5) M code signal, using a ADC 708-2. In this embodiment, the ADC 708-2 performs IF sampling at 65 MHz or any other suitably chosen sample rate. As shown in
It should be noted that resolution converter 712-1 was described above, and narrowband receiver DSPs 714-1 and 714-3 are configured to operate similar to narrowband digital receiver signal processor 108 except that they operate on the upper sideband and lower sideband after a resolution converter. In some embodiments, narrowband receiver DSPs 714-1 and 714-3 may be combined into a single combined narrowband digital receiver signal processor, as described in
Jam Resistant Acquisition Circuit and System for Processing Narrowband Signals
Modern GPS M and P(Y) code receivers use multiple parallel correlators to rapidly search time and frequency hypotheses in parallel. Each hypothesis may represent the possible time and frequency offsets of the signal from a receiver's local estimate of time and frequency. One approach to implementing a large number of correlators in parallel is to time share the same logic (e.g., multiply and accumulate operations) over and over by running the receiver's processor at a rate that is much faster than the incoming sample rate. In this approach, Rc=chip rate and assume that the physical correlators are time shared by processor operating at a clock rate fc>>2Rc.
Further, letting the number of physical correlators be denoted by Np, the number of time correlations performed in parallel is given by Ncorr. In some embodiments, this number describes an effective number of time correlators and is given by
Because the number of correlators is related to the time searched in parallel, the time to acquire increases inversely proportional to the number of correlators. For example, with the NASS system, it is easy to show that, for the same number of physical correlators and processor clock rate, a BOC(10,0.5) receiver can search hypothesis up to 100 times faster when no jamming is present.
In some embodiments of a NASS, the TTFA can be expressed in terms of the number of hypothesis searched divided by the number of hypothesis searched in parallel all multiplied by the overall signal dwell period. The overall signal dwell period is given by the product of the coherent integration period, Ti multiplied by the number of noncoherent integrations, Nnc. This total number of noncoherent integrations is typically limited to a practical level so that its duration does not exceed about 10 seconds depending on the dynamical constraints imposed on the receiver.
Therefore, the TTFA is given by
where Ti is coherent integration time, ΔT is the initial time uncertainty (ITU), F ae the number of frequency hypothesis searched in parallel, Δf is the initial frequency uncertainty, Rc is the chip rate, Nnc is the number of noncoherent integrations. The number of time hypothesis to search is given by ΔT·2Rc assuming 2 samples per chip, fc is the acquisition engine clock rate, and Np is the number of physical correlators.
is the total number of correlators used in an active parallel correlator implementation such as the one described in P. A. Dafesh and J. K. Holmes, “Practical and Theoretical Tradeoffs of Active Parallel Correlator and Passive Matched Filter Acquisition Implementations, “Proceedings of the IAIN World Congress and the 56th Annual Meeting of The Institute of Navigation, 2000. In other embodiments and passive matched filter may be used having a matched filter length that may be adapted to different coherent integration periods. It should be noted that Nnc increases slowly with decreasing chip rate due to the fact that the processing gain changes approximately linearly with chip rate, Nnc is a nonlinear function of the processing gain, and Rc2 decreases rapidly with decreasing chip rate. Using this equation, TTFA and AJ performance may be improved, thereby also improving TTFF. The TTFF is given by
TTFF=TTFA+t+tx+tdata Equation (3)
where TTFA is the time to first satellite signal acquisition given previously, tdata is the time to read the data message if navigation data is obtained from the satellite signal. If this data is obtained from a data assistance channel, the value of tdata may be greatly reduced or eliminated. tx is comprised of the time to acquire the remaining satellites, loop settling times, and time to compute a navigation solution. Additional time may be required to compute a first fix depending in a specific receiver implementation.
Note that the number of hypothesis per unit time is also proportional to the chip rate. Lower chip rates result in fewer hypotheses to search for a given initial time uncertainty.
Because TTFA∝Rc2Nnc, for the exemplary NASS (BOC(10, 0.5)) signal, an acquisition time speedup of up to 100 times is possible, compared to a BOC(10,5) signal when jamming isn't present. For the case of higher jamming such as when the J/S level is 30 dB or higher, a lower speedup is observed. A greater benefit under jamming may be obtained by employing a longer coherent integration period, e.g., 100 ms even without an AJ processor. The performance gains in table 800 shown in
In one embodiment, by employing dataless NASS signal and long coherent integration times up to 100 ms or longer, a net benefit is observed for the exemplary NASS system as compared to the conventional wideband M code signal. In other words, since the number of noncoherent accumulations depends on the effective carrier to noise ratio, which increases with coherent integration period and effective signal bandwidth. For a given NASS chip rate and J/S level, a corresponding optimum coherent integration period can be selected to minimize acquisition search time and achieve superior performance compared to a wideband signal receiver. In the current example, an optimal NASS coherent integration period was selected between 10-100 ms. In other examples, a longer range of coherent integration periods may be used to achieve even improved performance.
In some embodiments, an optimal coherent integration period may be optimally selected as a function of the effective carrier power to noise spectral density Ratio, as defined by
where Beff is an effective jammer bandwidth given by the inverse of the spectral separation coefficient between the signal having power C and Jammer having power level J, and N0 is the noise power spectral density in dBW/Hz. This equation may also be expressed in terms of J/S, as defined by
where S=C is the signal power. In these instances, the optimal coherent integration period may be selected to minimize TTFA for a given probability of detection and probability of false alarm where the number of noncoherent integrations is a function of the probability of detection and probability of false alarm and the coherent integration period. In other embodiments, the optimal coherent integration period is selected to minimize the overall dwell period, where the overall dwell period, τd is given by the product τd=TiNnc, where TTFA∝τd. In some embodiments, this minimization may be computed as a function of the effective carrier to noise ration ahead of time and pre-programmed into the receiver using a lookup table. In other embodiments, the minimization may be computed in the receiver after measurement of the effective carrier to noise power spectral density ratio. In either embodiment, both the dwell period and the TTFA are minimized as a function of the coherent integration period.
The combined effects of long coherent integration times and 10× or lower NASS chip rates enable enhanced performance even at higher J/S levels. This enhanced performance may be achieved even without an AJ processor.
See, for example,
The transmitted data is therefore multiplexed onto N channels, each processed separately to take advantage of the significantly improved dynamic range and ADC precision for each channel. This allows for greater overall AJ performance as compared to the wideband communication system receiver. The outputs of each of the N channels is fed into signal demodulator and combiner 910, which demultiplexes the data contained on the N channels, to reconstruct the original channelized data. Each channel may contain M subchannels corresponding to elements of a multi-element antenna. In such an example, there may be N×M total channels fed into N AJ processors, which may apply spatial nulling and/or beamforming techniques to remove jammers in each of N channels. In other embodiments, the channels may be part of an Orthogonal Frequency Division Multiplexing (OFDM) system used for wireless communications such as 4G or 5G, or alternatively, in Wi-Fi systems such as 802.11 or similar systems.
Put simply, with the embodiment shown in
Alternatively, other constant envelope or nonconstant envelope signal combining techniques may be used to combine constant envelope signals at different frequencies. This may enable use of high-resolution ADCs, which have significantly greater number of bits. For single element AJ techniques, there is only one ADC at each frequency. However, with multi-antenna AJ techniques, there may be M ADCs at each frequency (Channel) for a total of M×N ADCs, each operating at a low sample rate≤2 MHz.
Existing AJ solutions rely on the processing of wideband signals such as M code (for navigation) or protected tactical communication for Satcom. These signaling approaches are limited by availability of spectrum and by availability of high precision, wide bandwidth ADC technology.
By jointly designing the signal with consideration for dynamic range of AJ, the electronics in some embodiments improves AJ performance. Further some embodiments may relax spectrum availability requirements, enable better spectrum compatibility with other signals, and enable low SWAP receivers with faster signal acquisition times.
The embodiments may also allow for up to 44 dB improvement in AJ performance. This can be seen by comparing BOC(10,0.5) NASS technique using an ADC with 21 effective bits as compared to the conventional BOC(10,5) signal receiver and AJ processor using an ADC with 12 effective bits.
Additional improvements in TTFF may be achieved by selecting an optimal coherent integration period (e.g., 10-100 ms) as a function of jammer level.
In one embodiment, the narrow band receiver acquisition circuit performs an initial parallel correlation over a shorter coherent integration period of time period of Ti0 using a vector correlator that performs Ncorr time correlations in parallel. See, for example,
In addition to the parallel time hypothesis search conducted by the vector correlator in
Following the vector correlator, a NFFT tap (point) FFT is performed, which produces NFFT×Ncorr time frequency cells, each with a coherent integration period of Ti=Ti0×NFFT. In alternate embodiments, a Discrete Fourier Transform (DFT) may be used instead of an FFT.
In some embodiments, the number of time-frequency hypotheses searched in parallel is given by Ncorr×NFFT, in other embodiments, the number of time-frequency hypotheses searched in parallel is given by Ncorr×αNFFT where α<1. For example, as described below, only the center ½ of the bins may be searched in order to limit the frequency quantization loss to 0.91 dB. In this case, the number of cells searched in parallel is 0.5×Ncorr×NFFT.
In the case of a BOC signal—a second vector correlator may be used to operate on the Î and {circumflex over (Q)} signals of the USB (not shown), while a first vector correlator operates on the Î and {circumflex over (Q)} signals of the LSB (not shown).
The mean value of the correlator 1200 output provides a measure of the signal power. This power, however, is weighted by a sin(x)/x function, resulting in a frequency quantization loss.
In a parallel frequency search implementation (using an FFT), the total frequency uncertainty, Δf, is broken up into some number of segments of width ΔfFFT If the FFT searches the entire frequency uncertainty in parallel, Δf=ΔfFFT. As described above, the search is conducted by first performing a short integration over a period Ti0<Ti. Consider first, the case of an FFT without zero padding. In such a case, the notation N0FFT is used to denote the size of an FFT without zero padding and NFFT is used to denote the size of an FFT with zero padding.
T
i
=N
0
FFT
T
i0 Equation (6)
The frequency quantization loss in the first short integration is therefore related to the region searched in parallel by the FFT, ΔfFFT, according to
for the case of a parallel search over the region ΔfFFT (this loss is may be called the FFT outer bin loss). If there were no outer bin loss, then the
To limit the outer bin loss predicted by Equation (7) to, for example, 0.91 dB, ΔfFFT is selected so that
In other words, the total region spanned by the FFT is equal to the ½ the sample rate into the FFT, which is equal to the integrate and dump rate, or just
Thus, in order to maintain frequency quantization losses (due to frequency quantization in regions of width ΔfFFT) to 0.91 dB, Equations (6), (8), and (9) imply that only one-half of the FFT bins are tested for signal, or α=½. If, for example, the outer FFT bins were tested for signal, they would suffer a loss could be tested for signal, the loss given by substituting
into Equation (8), resulting in
While we are only testing the center half for signal, the fine-level quantization (for the parallel search using an FFT without zero padding) is simply given by the ratio the FFT sampling rate to the number of points in the FFT by
where δf0 is also equal to the FFT bin separation under. Substituting Equation (6) for N0FFT and Equation (8) for FsFFT into Equation (11) leads to the following result for the search bin size
which is the resolution required to maintain 0.91 dB of frequency quantization loss for an FFT implementation without zero padding.
And the region searched in parallel is given by
A similar loss occurs in the FFT integration (leading to Equation (6)). This FFT-specific loss, denoted by the FFT-bin loss, is due to the FFT minimum response, which occurs at the midpoint between two bins.
Thus, in some embodiments, the FFT is zero padded resulting in a higher frequency resolution of
and the region spanned by the FFT is by
where α=0.5 was selected to maintain outer bin losses to 0.91 dB. In other embodiments, α may be selected to trade the number of frequency hypotheses searched in a parallel with overall implementation loss of the acquisition circuit. Note that the magnitude outputs of the FFTs shown in
The features, structures, or characteristics of the invention described throughout this specification may be combined in any suitable manner in one or more embodiments. For example, reference throughout this specification to “certain embodiments,” “some embodiments,” or similar language means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, appearances of the phrases “in certain embodiments,” “in some embodiment,” “in other embodiments,” or similar language throughout this specification do not necessarily all refer to the same group of embodiments and the described features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.
It should be noted that reference throughout this specification to features, advantages, or similar language does not imply that all of the features and advantages that may be realized with the present invention should be or are in any single embodiment of the invention. Rather, language referring to the features and advantages is understood to mean that a specific feature, advantage, or characteristic described in connection with an embodiment is included in at least one embodiment of the present invention. Thus, discussion of the features and advantages, and similar language, throughout this specification may, but do not necessarily, refer to the same embodiment.
Furthermore, the described features, advantages, and characteristics of the invention may be combined in any suitable manner in one or more embodiments. One skilled in the relevant art will recognize that the invention can be practiced without one or more of the specific features or advantages of a particular embodiment. In other instances, additional features and advantages may be recognized in certain embodiments that may not be present in all embodiments of the invention.
One having ordinary skill in the art will readily understand that the invention as discussed above may be practiced with steps in a different order, and/or with hardware elements in configurations which are different than those which are disclosed. Therefore, although the invention has been described based upon these preferred embodiments, it would be apparent to those of skill in the art that certain modifications, variations, and alternative constructions would be apparent, while remaining within the spirit and scope of the invention. In order to determine the metes and bounds of the invention, therefore, reference should be made to the appended claims.
This application claims the benefit of U.S. Provisional Application No. 62/872,208, filed on Jul. 9, 2019. The subject matter thereof is hereby incorporated herein by reference in its entirety.
Number | Date | Country | |
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62872208 | Jul 2019 | US |