WO2006085928A2 - Passive distance measurement using spectral phase gradients - Google Patents
Passive distance measurement using spectral phase gradients Download PDFInfo
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- WO2006085928A2 WO2006085928A2 PCT/US2005/020668 US2005020668W WO2006085928A2 WO 2006085928 A2 WO2006085928 A2 WO 2006085928A2 US 2005020668 W US2005020668 W US 2005020668W WO 2006085928 A2 WO2006085928 A2 WO 2006085928A2
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S11/00—Systems for determining distance or velocity not using reflection or reradiation
- G01S11/02—Systems for determining distance or velocity not using reflection or reradiation using radio waves
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S11/00—Systems for determining distance or velocity not using reflection or reradiation
- G01S11/12—Systems for determining distance or velocity not using reflection or reradiation using electromagnetic waves other than radio waves
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S11/00—Systems for determining distance or velocity not using reflection or reradiation
- G01S11/14—Systems for determining distance or velocity not using reflection or reradiation using ultrasonic, sonic, or infrasonic waves
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S13/00—Systems using the reflection or reradiation of radio waves, e.g. radar systems; Analogous systems using reflection or reradiation of waves whose nature or wavelength is irrelevant or unspecified
- G01S13/02—Systems using reflection of radio waves, e.g. primary radar systems; Analogous systems
- G01S13/06—Systems determining position data of a target
- G01S13/08—Systems for measuring distance only
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S13/00—Systems using the reflection or reradiation of radio waves, e.g. radar systems; Analogous systems using reflection or reradiation of waves whose nature or wavelength is irrelevant or unspecified
- G01S13/02—Systems using reflection of radio waves, e.g. primary radar systems; Analogous systems
- G01S13/06—Systems determining position data of a target
- G01S13/08—Systems for measuring distance only
- G01S13/10—Systems for measuring distance only using transmission of interrupted, pulse modulated waves
- G01S13/103—Systems for measuring distance only using transmission of interrupted, pulse modulated waves particularities of the measurement of the distance
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S15/00—Systems using the reflection or reradiation of acoustic waves, e.g. sonar systems
- G01S15/02—Systems using the reflection or reradiation of acoustic waves, e.g. sonar systems using reflection of acoustic waves
- G01S15/06—Systems determining the position data of a target
- G01S15/08—Systems for measuring distance only
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S15/00—Systems using the reflection or reradiation of acoustic waves, e.g. sonar systems
- G01S15/02—Systems using the reflection or reradiation of acoustic waves, e.g. sonar systems using reflection of acoustic waves
- G01S15/06—Systems determining the position data of a target
- G01S15/08—Systems for measuring distance only
- G01S15/10—Systems for measuring distance only using transmission of interrupted, pulse-modulated waves
- G01S15/101—Particularities of the measurement of distance
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S7/00—Details of systems according to groups G01S13/00, G01S15/00, G01S17/00
- G01S7/02—Details of systems according to groups G01S13/00, G01S15/00, G01S17/00 of systems according to group G01S13/00
- G01S7/40—Means for monitoring or calibrating
- G01S7/4004—Means for monitoring or calibrating of parts of a radar system
- G01S7/4021—Means for monitoring or calibrating of parts of a radar system of receivers
Definitions
- This invention generally pertains to the measurement of the distance to a remote object More particularly, it concerns passive monostatic ranging, that is, measuring distance using electromagnetic or acoustic waves without illuminating, or querying, the object with electromagnetic or acoustic energy, and without involving spatial parallax
- passive monostatic ranging that is, measuring distance using electromagnetic or acoustic waves without illuminating, or querying, the object with electromagnetic or acoustic energy, and without involving spatial parallax
- a fundamentally new way is disclosed for extracting distance information from the spectral phase profile, i e the phase distribution across a set of frequencies, m a received signal, without requiring it to be reflected or transponded
- the invention more specifically concerns extraction of this information as a hitherto unrecognized effect of the wave nature of electromagnetism and sound similar to the Doppler effect, but using only on the instantaneous source distance and receiver-side operations
- the timing approach is constrained by problems of scalability, power and antenna size, since illuminating a target at range r requires a power P oc r ⁇ ⁇ x and equivalently, the range is limited to r max oc P 1 / 4 for an available power P
- the power requirement can be alleviated by improving the receiver technology, by using very low noise receivers and large antennas to collect more power
- a Freeman and E Nielsen of JPL have proposed a radar for mapping Kuiper Belt objects using a transmitter power of 10 MW, but located in space and with an antenna diameter of 1 km
- the need for illumination severely constrains radar technology
- Even with very high power ground stations m NASA's Deep Space Network accurate ranging of spacecraft m deep space has been possible only by using the onboard telemetry transponder to return a modulated signal instead of an echo, and thus reducing the power requirement to r ⁇ naj .
- a ranging method that does not depend on illumination, and would instead use the target's own emissions would be desirable both as an alternative m existing radar applications as well as for novel applications that are currently impossible or impractical Its range would be governed by the inverse square law of one-way propagation m free space, instead of the fourth power law, and it would be therefore usable over much longer distances Since no phase correlations with illumination sources would be required, the computation, if any, should be vastly simpler than that m current passive radars A cellular device employing it would be able to gauge its distance from the nearest base station accurately from the latter's transmissions In optical fibres and transmission lines m integrated circuit chips, degradation or breakage could be detected with absolutely no interruption of service, scheduled or otherwise
- Wavelets analysis A related description of the present invention is as a technique involving continuously varying frequency or time scales.
- a powerful means for analysing multi-scale phenomena is now available m wavelet transforms
- a fundamental difference remains, however, that the wavelet techniques are concerned with the scale distribution of the source signal, which cannot depend on the receiver's distance
- the scale variance is incorporated in the receiver, and the distance information is then associated with each individual frequency observed, independently of wavelet or other radar processing techniques that may be applied to the observations
- a second problem particularly limiting the accidental category is that the invention requires an exponential profile of variation, or else the result is an even more complex form of dispersion from which the distance correlations are all the more difficult to recognize It is hardly surprising, therefore, that transitory behaviour of tuned systems and spectrometers have been mostly ignored m prior art, with the exception of frequency modulation systems m communication In the latter case, not only are the transition rates linear and limited in magnitude, but the modulation as such is applied at the source itself, so the possibility of distinguishing distance correlations is nonexistent
- variable tuners and gratings Two problems have served to limit prior discovery, the first being that all such variable systems, like frequency modulation, are designed primarily for linear variation The second is that most such devices, especially the more accurate ones, are designed for controlling static selection of wavelength or frequency, whereas the invention concerns changing of the selection during observation
- PLLs phase-locked loops
- Continuously variable diffraction gratings are available in the form of acousto-optic (Bragg) cells, but m this case, the grating is formed by an acoustive wave whose wavelength cannot be varied instantaneously across the spatial observation window
- a fourth class of problems that hitherto prevented discovery is especially clear in the case of digital signal processing commonly applied to both acoustic and radio signals
- the theoretical treatment was hitherto exclusively m terms of amplitudes, frequencies and phases, so the the source distance would be hidden in the phases and the start-time delay
- the data is conceptually decoupled from the sources and their distances by sampling and digitization, making a reverse correlation with the source distances all the more unintuitive
- the source distances generally manifest only as start-up delays m the time domain, with no real value as the source of the distance information
- logical connection to the physical distance is maintained, as will become clear, by applying the inventive procedure only at the frontend of the receiver, and the source of the distance information is the spectral phase profile, applicable to a continuous signal, rather than the start-up delay, which would have required an RTT reference once again
- NASA's deep space technique includes tracking of residual Doppler shift in the modulated return signal, which has particularly revealed an "unmodelled acceleration” in "all six missions” to date involving spin-stabilized spacecraft, as reported by J. D. Anderson and others in Physical Review D, vol. 65, April 2002.
- the theory also fundamentally differs from a more naive relativistic intuition, attributed to Eddington, that a uniform expansion of the universe would be equivalent to a uniform shrinkage of every atom, m that the scale of the atomic structure cannot be affected by macroscopic phenomena like creep More significantly •
- the creep rate would be different onboard a spacecraft, on another planet or m another solar system, and further, vary with time m all cases as the tidal stresses evolve
- the second discrepancy is the associated idea that source distance information can be present in received radiation only as the spatial curvature of the wavefront, which requires multistatic reception to exploit, or the inverse-square law intensity decay, which can be exploited only for "standard candles” of known source intensitites.
- the presence of source distance information in phase envelopes, as revealed by pulse radar imaging, has been unobvious because it cannot be regarded as a statistical result, given that the statistical nature of quantum wavef ⁇ nctions concerns their amplitudes rather than their phases.
- the present invention concerns detector state transition events representing photons that are inherently nonsinusoidal, and therefore capable of bearing distance information. There is no loss of generality either, as will become clear. These concerns are, of course, irrelevant in acoustic applications.
- a primary object of the present invention is to provide a very general passive ranging technology which would scale to much greater distances and be applicable to any and every observable target.
- a related object is to dramatically reduce the required operating power.
- a secondary object is to improve safety and health by reducing exposure to radar illumination.
- Another secondary object is to simplify the measurements and the computations involved in radars and sonars.
- a further motivating object is a deeper understanding of wave properties which are fundamental to electromagnetism, quantum and relativity theories, and of the mechanics of interaction between radiation and matter.
- Yet another secondary object is providing practical means for measuring the microscopic damage of tidal forces both on earth and in interplanetary missions.
- a spectrally sensitive frontend means such as a tuned antenna or a telescope mirror
- a continuous modification at a normalized rate H (per second) measuring resulting normalized shifts z ⁇ ⁇ / ⁇ (dimensionless) of one or more frequencies ⁇ in the spectrum of the received waves, and computing the distance r to the target using the formula
- A is variously called the wavevector or wave number, and ⁇ is the wavelength.
- the first term on the right is the path contribution to the instantaneous phase.
- a phase increment can arise from this term due to either a change of distance ⁇ r or a change in the selection of the wavevector Ak; that is,
- the first term on the right, k ⁇ ⁇ r, is involved in both the Doppler effect and traditional phase-based methods like holography and synthetic aperture radar, which depend on phase differences at individual frequencies.
- the present invention concerns the second term, which may be rewritten as
- pulse radar imaging as discussed in the Background, in which the illuminating pulse train is equivalent to a "comb" of frequencies, providing frequency- diversity for differentiating target features along the radial direction. Its range is limited, however, as it uses fixed Ak, and active illumination.
- equation (4) For unlimited range, a na ⁇ ve application of equation (4) would require accurate selection of pairs of close frequencies differing by a small Ak and equally precise measurement of their instantaneous phases, since for T — ⁇ oo and 0 ⁇ ⁇ ⁇ oo, equation (4) implies ⁇ A: - ⁇ O, and would lead to issues of mutual dependence and uncertainty, whereas only the values of Ak and A ⁇ should be relevant.
- the present invention concerns further simplification by the use of rates of change for either factor in equation (4), i.e. sweeping across the spectrum, to obtain the target distance as the ratio
- the notation k instead of k, indicates selection rather than an intrinsic property of an incoming wave.
- the numerator ⁇ represents a shift in the measured frequency, and is almost always easier to measure more precisely than phase. Its proportionality to r means that the shift ⁇ cannot be confused for a calibration error introduced by the modification.
- the denominator dk/dt is the inventive modification to the spectral means, defining the rate of change of its frequency selection, and as the applied variable, it can be precisely controlled. Equation
- ⁇ ⁇ kc is a frequency instantaneously acted upon by the frontend, together with the definition of the normalized modification rate
- the invention makes two improvements over the cosmological distance scale critically needed for ordinary terrestrial and near space distances.
- Frequency selection is ordinarily governed by the orthogonality condition
- equation (5) seems to indicate the latter as equation (4) specifically concerns a differential
- phase gradient was unused in all of physics: it will be shown in the Detailed Description that it signifies a temporal analogue of the spatial curvature of wavefronts.
- the scanning of this phase gradient yields the frequency shift factor 1 + rH/c at each k.
- the phase gradient forms envelopes across the spectrum analogous to the wavefronts formed across space, as mentioned
- the present invention constitutes exploitation of a temporal form of parallax, in which the modification rate dk/dt is the corresponding form of angular displacement of the receiver relative to the source
- m equation (3) which concerns the other term m equation (3) and involves the recording and reproducing of phase differences A ⁇ due to spatial displacements ⁇ r at individual frequencies, the angle of view does relate correspondingly to spatial frequencies
- the "memory" of the source lies embodied in the phase gradient pattern across the frequencies, rather than the waveform pattern of any of them This phase gradient memory gets overwritten whenever the phase evolution deviates from equation (2) nonuniformly across frequencies, so that it would be generally unaffected by dispersion-free deflection, but would take on the distance information of dispersive or reemitting scatterers.
- the expected transparency of dispersion-free deflectors is hardly special and would not pose a serious problem as the transparency would be limited to specific frequency bands and would be absent around the edges of the deflecting body or medium.
- the inventive modification is suitably applied to the physical frontend means.
- the inventive modification in a receiver using a resonant cavity, consists of continuously varying the length of the cavity.
- the modification similarly comprises continuously varying one or more tuning elements in the circuit, such as an inductor, a capacitor or a resistor, or a combination of such elements in some proportion.
- the inventive modification In a receiver using a diffraction grating, the inventive modification consists of uniformly varying the grating intervals during observation. In a receiver using a refractive element like a prism, the modification consists of uniformly varying the optical thickness of the element, that is, its thickness or its refractive index. In receivers employing sampling as frontend means and computing the received spectrum from the sampled data, the inventive, modification correspondingly consists of continuously varying the sampling interval.
- the spectral sensitivity in the sampling frontend lies in the calibration of the computed spectrum in terms of the sampling interval, since a given sequence of sampled amplitude data would always yield the same numerical output, which would represent different frequency ranges depending on the actual sampling (time) interval that was used in the sampling frontend.
- the desired controlled variation dk/dt is obtained by not compensating for the variation of the sampling interval in the subsequent computation of the spectrum.
- uniformly sampled values may be interpolated to simulate the interval variation, provided the original sampling interval is sufficiently fine and a large enough number of samples are available to permit a meaningful interpolation, since the inventive procedure calls for exponential variation of k in order to achieve a steady, desired value of H, as implicit in equation (7).
- the spectral means may be reset and the inventive modification repeated at short time intervals, in order to facilitate the measurement of the frequency shift.
- the repetition period can be made as short as micro-seconds at optical frequencies, so that the shifted spectra can appear steady to the human eye.
- An immediate variation consists of inverting the direction of the inventive modification between alternate repetitions, reversing the sign of H. This would not only avoid having to explicitly reset the spectral means, but would also avoid losing the incoming energy during the resets, and provide a differently shifted spectrum to compare with for the purpose of identifying and measuring the shifts.
- a related variation is to employ a second receiver in parallel, unmodified or with a different modification rate, to provide the comparison.
- Another general variation of the invention is to briefly increase or decrease the inventive modification H so as to magnify the shifts for studying specific targets or their features. By equation (1), the magnification would manifest instantly at all r.
- the inventive method comprises constructing a means for spectral selection or decomposition out of the same materials as the instruments, combining this means with (or building it into) a telescopic means for observing distant known objects, such as stars or galaxies, and determining the frequency shifts in the radiation received from these objects to obtain a corresponding mean value for H, say HQ, which directly quantifies the (local) natural creep rate (or other natural causes).
- Yet another variation is to apply nonzero modification rates H to a mix of incoming signals from multiple targets, and to thereby separate the targets by comparing the resulting shifted spectra.
- the principal advantage of the present invention over most known distance measuring techniques is its truly passive nature. This enables its use over larger distances than any current technology, in both near and deep space, as it leads to an r max oc P 1 / 2 power-range law, and avoids dependence on a reference illumination.
- the inventive method further provides a simple means for separating targets and target features by their radial distances to augment or simplify both active and passive radar systems, as it does not require phase or round-trip timing correlation with reference illumination.
- This correlation is the reason for much complexity in the radio-frequency (RF) section of existing monostatic radars, and the realizable isolation between the sending and receiving sides sets a limit on their performance.
- the present invention would enable the two sides of the RF section to be decoupled without loss of information.
- Yet another advantage of the present invention is the elimination of about half the total propagation delay incurred in most current radars, taken by the interrogating pulse.
- the RTT would be a sizeable fraction of a second, depending on the range of the target, and halving it would mean greater accuracy of tracking.
- the usual procedure for cellular power control is to have the base station respond to an initial transmission from a mobile device, instructing the latter to raise, or more likely lower, its transmitting power. If the mobile units could even approximately but reliably estimate their distances from the base stations, they could avoid emitting making initial transmissions at higher power, which would not only better conserve their batteries, but also reduce interference and allow better use of the available bandwidths.
- the power setting instructions from the base stations could be largely eliminated, releasing more channel time for actual communication.
- the present invention would enable reliable base station distance estimation without RTT measurement, saving battery power as well as helping to improve service.
- phase reference elimination means that the requisite excitation can be applied at either end and have any waveform, so that the method can be employed continuously using the data stream itself while the line or fibre is in operation, and, importantly, with much less analytical complexity for determining the discontinuities and imaging their distribution along the physical channel.
- the present invention provides a ready means for separating signal spectra from different sources according to their distances, as mentioned, with numerous advantages. This would allow improved separation of signals overlapping in frequencies, for example, allowing CDMA cells to be made smaller, or communication bands to be reused even without code division, providing what could be referred to as source-distance multiplexing
- This distance separation capability would also simplify target separation in radar and sonar, and enable two dimensional imaging similar to synthetic aperture radar but without coherent illumination.
- the separation would enable radar receivers to become more resilient to jamming ("unjammable radars").
- inventive frequency shifts are indeed as general and fundamental as the Doppler effect.
- the invention may be applied, therefore, to any kind of propagating waves, including sound, as mentioned, and even the de Broglie waves of matter.
- Fig. 1 is a graph illustrating the operating principle of the present invention.
- Fig. 2 graphically illustrates the notion of temporal parallax given by the present invention.
- Fig. 3 shows a schematic block diagram of the preferred embodiment of the present invention.
- Fig. 4 illustrates the physics of the inventive modification in a receiver using a resonant cavity.
- Figs. 5 illustrates the physics of the inventive modification in a receiver using a diffraction grating.
- Figs. 6, 7 and 8 show three successive snapshots in time of the setup of Fig. 5 as the modification is applied.
- Fig. 9 shows the tuning section of a receiver using a "tank circuit" to which the invention may be applied.
- Fig. 10 is a plot illustrating the extraction of the phase gradient in a receiver using sampling and computation of the spectrum, by varying the sampling interval according to the present invention.
- Fig 11 shows the time-dependence of the wavelength of a receiver mode due to the inventive modification
- Fig 12 illustrates how the present invention integrates energy across successive wavelengths
- Figs 13 and 14 illustrate tidal creep on earth and on spacecraft, respectively, which can now be measured using the present invention
- the principle of the invention is best illustrated by the graph m Fig 1 showing how the phases of waves of different frequencies, ⁇ o, ⁇ i , , emitted by a target progress with the radial distance r from the target
- the nodes [911] and the antmodes [912] of a low frequency ⁇ o have greater spatial separations than the nodes [913] and the antmodes [914] of a higher frequency, say W 2
- the wavefronts recorded and reproduced in holography are similar phase contours over space, instead of time as represented by the frequency domain
- Fig. 2 illustrates the related notion of temporal parallax, which particularly explains the elimination of the need for a temporal, or phase, reference for the measurement of a target distance r in the present invention.
- the figure shows a plot of the inventive frequency shifts given by equation (1) for several values of H for a point source initially at a first location [850] at distance r, and later at a second location [860] at r' > r.
- an incoming spectral distribution F( ⁇ ) [730] would appear shifted in frequency, under the inventive modification of rate H ⁇ (line [711]) to F( ⁇ [) [731], and under a rate Ho > Hi (line [712]) to around ⁇ 2 ' [732].
- rate —H ⁇ line [721]
- the distribution would be shifted to around
- the preferred embodiment concerns a receiver of incoming electromagnetic, acoustic, gravitational or matter waves [900] from a target source or scatterer [800] comprising incoming frequency components ⁇ F( ⁇ ) ⁇ , the receiver including a backend spectral analysis or detection means [220], and a frontend tuner or filter means [200] to receive the incoming waves at its input [100], such that the frontend influences the spectral selection at the backend.
- the invention comprises
- a modifier means [400] to apply a controlled rate of change dk/dt to the frontend means [200], thereby producing a shifted spectrum ⁇ F( ⁇ ) ⁇ at the output of the frontend means [200], in turn causing shifts ⁇ ⁇ D at one or more frequencies, or in a frequency band, selected by the backend means [220];
- a frequency shift detector means [300] to determine the inventive frequency shifts ⁇ from or within the output of the backend means [220]; • a di&tance computer means [320] to compute, as its output [120], the distance r to the target [800] using the output of the shift detector [300] and the instantaneous value of dk/dt being applied at each k,
- radio and television receivers include mixers that down-shift the incoming carrier to preset intermediate frequencies, and tuning elements that are selective of the latter, but the down-shift itself is not of interest
- the obvious frontend would be the objective lens or mirror, but the eyepiece lens could also be selected instead, for applying the inventive modification, m either case, the backend would be the observer's eye or a photodetector array as in most astronomical instruments today Likewise, in a diffraction spectrometer, a grating or a set of slits would be likely candidates as the frontend means of the present invention, and the backend would be again a photodetector array or photographic film recording the spectrum In a digital system performing digital Fourier transform (DFT), the DFT constitutes the backend and the frontend is the data sampling subsystem Prior to the present invention, these systems would have been viewed as containing integral spectral analyzer units, indicated by the dotted line [210]
- DFT digital Fourier transform
- the backend detector or circuit ordinarily receives energy only m a narrow band around the frequency selected by the frontend
- the backend is not usually designed to perform spectral analysis of its own, but to measure the amplitude or energy of the selected frequency
- incoming waves [900] from the target [800] are fed by an input coupling means [100], such as an antenna, to the frontend means [200] directly or m an alternative form such as a voltage waveform
- the backend means [220] extracts, at one or more frequencies ⁇ , the complex valued Fourier coefficients
- the spectral means admits a continuous range of frequencies ⁇ , corresponding to the inverse Fourier transform
- the present invention thus makes the first nontnvial use of A; as a control variable by providing for
- Equations (20) specify the variation of the control variable k, or equivalently ⁇ , required to maintain a steady value of if, whereas equations (10), (12) and (13) represent achieved shifts in the received spectra due to the instantaneous value of H .
- the frequency scale factor (1 + rH/cj introduced by the inventive modification is clearly independent of relativistic causes, such as falling in a gravitational potential well, which would yield a similar, continuous change of the receiver's frequency scale.
- it would require falling steadily at 128.4 km/s in 1 g potential gradient to simulate the Hubble redshifts, i.e. for producing H « 10 ⁇ 18 s" 1 , let alone the enormous larger values necessary for use at terrestrial and near space scales.
- the scale factor in the present invention is mundane in this sense, and the effect would be limited to a "scaling zone" comprising the frontend [200] and the backend [220], demarkated by the dotted line [210].
- the modification rate may be continued for several periods before resetting or reversal.
- the backend spectrum analyzer [220] and shift detector [300] may be directly designed for the expected shifted frequency range, for example, for the visible band but paired with a fronted for microwaves.
- this conclusion would be premature, and the preceding example should really not be construed to imply that only small shifts would be available.
- Fig. 4 illustrates this new physics resulting from the inventive modification in a receiver using a resonant cavity [210] for frontend spectral selection, and a probe [222] leading to a backend circuit or subsystem for measuring a distinctive spectral property, such as an amplitude or intensity peak of an atomic spectral line, or the variation of the intensity across a band of frequencies to be successively selected at the frontend in the overall course of observation.
- the object is to measure the distance r to a target source [800] emitting (its own or scattered) radiation [900], as shown.
- the cavity [210] is initially resonant at a wavelength XQ at time to-
- the standing wave pattern [910] of this fundamental mode is shown extended towards the target, to illustrate that the fundamental mode could be excited by a source of that frequency located around any of the antinodes [912], and would be unlikely to be excited if the source were at any of the nodes [911] lying inbetween the antinodes as shown. Excitation of the fundamental mode thus corresponds to detecting the presence of a source, but is ordinarily inadequate for determining the distance r to the source (target) [800] as r could correspond to any of an infinite number of antinode locations [912] spaced at increments of ⁇ o/2 from the cavity.
- the nodes and the antinodes move towards the cavity, to new locations [913] and [914] respectively at £ 3 , in proportion to their distances.
- the antinode nearest to the target [800] also moves towards the cavity.
- the receiver's representation of r will remain unchanged if and only if the target were moving as well just to maintain its phase relative to the changing instantaneous resonant mode of the cavity, i e moving closer to the receiver as shown by the successive "virtual positions" [810]
- the second term is the "real" Doppler effect due to relative motion ( ⁇ dr/dt) if any between the target (source) and the receiver,
- Equation (25) means that the incoming frequency ⁇ actually selected by a changing resonator is not its (instantaneous) resonance frequency ⁇ , but a proportionally larger or smaller value depending on the rate of change H, and the distance r to the source of the incoming radiation or signal, as previously explained with Fig 3 This enables the measurement of r by controlling H according to the present invention (equation 1)
- Fig 5 shows the same physics resulting from the inventive modification in a receiver employing a diffraction grating [230] for spectral analysis
- a receiver typically includes an achromatic lens means [240] to focus the rays diffracted at an angle ⁇ to a point corresponding to ⁇ m the focal plane [241] of the lens
- n ⁇ l sm ⁇ , (26) where n is the order of diffraction
- the focal plane is calibrated to read off the wavelengths ⁇ , or equivalently the frequencies ⁇ corresponding to the diffraction angles
- the object of the inventive modification is therefore to cause the focal points to shift for the wavelengths present m the incoming signal
- the figure illustrates this intended effect, viz that every initially observed "image" spot [820] for frequency ⁇ should be shifted to a new image spot [830], corresponding to ⁇ of equation (25)
- the modification m this case comprises varying the grating intervals at successive times
- the figure explains the result of this variation
- the shifted image [830] is still the sum of contributions from different portions of the grating, as in traditional Fourier diffraction theory
- a ray [930] just emerging from the other end which would have faced a reduced grating interval [233] l m ⁇ l(t m ) ⁇ Io
- the gratmg intervals [231] and [233] seem to act concurrently from different regions of the gratmg, this desired effect cannot be achieved by spatial, static variation of the gratmg intervals, but can be obtained only by real
- Figs 6 through 8 are three successive snapshots in time explaining this process
- a wavefront along ray [920] which would have emerged from the gratmg at to, would be still "m flight” , and would be joined by the wavefront of the second set of rays [921] just emerging (at t ⁇ , Fig 7) , and still later by the wavefront of the third set of rays [922] emerging at ti (Fig 8) All of these wavefronts must arrive in phase at the focal plane, in order to combine constructively to produce the shifted image spot [830]
- the inventive modification does not affect the spatial distance traversed by the individual rays from the grating [230] to the focal plane [241] , nor the refractive index profile along their paths, notably at the lens [240].
- the optical path lengths, defined by the path integrals of the refractive index thus remain unmodified from conventional Fourier spectroscopy, where they are known to be equal.
- this incremental distance, resembling r' in equation (23) is constant, and its derivative is 0.
- the third term in equation (23) thus vanishes altogether, making the achieved frequency-distance relation even more exact than for cavity receivers.
- refraction involves a continuum of multiple paths.
- Fig. 9 shows the tuning section of a receiver using a "tank circuit" comprising an inductor [250] of value
- equation (22) may be transposed to
- the tuned circuit with the inventive modification could be employed, for instance, in the radio receivers of police, coast guard and other emergency services, enabling them to home in on distress calls accurately even without triangulation or radar support.
- Another application is transparent monitoring of transmission lines and optical fibres, as explained in the Summary. An alternative digital approach is described next.
- the inventive modification comprised varying these lengths exponentially per equation (20) in these cases.
- the analogous modification for a tuned circuit lay in similarly modifying one or more of its tuning elements. At lower frequencies and with sound, however, it is now more common to use sampling and digital filtering or computation of the spectrum.
- the only frontend tuning element is the "sampling clock" , and it follows intuitively that this must be somehow subjected to a controlled modification for once again obtaining the frequency shifts of equation (5).
- Fig. 10 illustrates how the phase gradient gets exposed by varying the sampling interval T.
- Equation (34) establishes that this increasing phase difference is in fact the same as that seen by a resonant cavity, as in Fig. 4, subjected to similar inventive modification of its length.
- the inventive method could be conceivably applied to de Broglie waves, such as in an atomic microscope, or to seismic waves in geology, as an alternative or supplement to triangulation.
- Another variation is to use a prism instead of a diffraction grating, the inventive modification being then applied by mechanical compression.
- Another variation, related to the resonant cavity and the tuning circuit frontends, is to use a tuned delay line as frontend, the inventive modification then consisting of varying the length of the delay line analogously to the length of the cavity.
- Yet another variation is to apply the inventive principle in reverse to determine extremely small creep rates under inertia!, electromagnetic or tidal stresses, by measuring the frequency shifts for known targets resulting from the creep.
- phase velocity c of a spectral component is independent of the spectral decomposition
- Theorem 1 (Source distance information) A sufficient condition for determining the distance to a distant source from its band-limited signal is that the output of the receiver be derived from a continuum of wave periods of different wavelengths in the signal
- Equation (4) implies, as mentioned following equation (4), that for r ⁇ oo, we need ⁇ A; — > 0 m order to keep the phase difference A ⁇ finite and constant In the limit, therefore, we need to effectively compare phases between frequencies that are mfmitesimally apart It might seem somewhat ironic that it is for nearby targets that we would need a large bandwidth ⁇ D Any radiation from a real source has nonzero Fourier spectral spread and more particularly, the Fourier components will have phases consistent with their common source location
- Observation (A) provides a necessary connection and the distance-frequency relation Observation (B) is of course the basis for capturing the relation, which is done m a manner involving time only m derivatives so as to eliminate the traditional need for a time or phase reference
- the cavity modes are instantaneously of a time-varying form, as shown m Fig 11, and satisfy the scaled translation invariance of equation (38), but the shifted frequencies arise from the phase differences between such a mode and the incoming waves as a phase difference wave.
- This difference wave is primarily seen by a subsequent stage of the receiver, identified as the backend means [220] in the preferred embodiment, Fig. 3 fed by the probe [222], so that the frontend resonator acts only as a filter, not as the final detector. This might be clearer with the modified diffraction grating of Fig.
- Fig. 11 illustrates the time-varying resonant mode of the cavity [210] of Fig. 4.
- the resonance wavelength changes, as in the prior figure, from A 0 to ⁇ i, ⁇ 2 , and so on, at the successive times to, t ⁇ , to, etc. If we string these successive wavelengths, we get the time-varying waveform [950] as it arrives at the cavity, though this is really an approximation, as the wavelength changes gradually and not discretely at the successive nodes.
- the reflected wave serves as the phase reference for the next wavefront, but only at successively decreasing wavelengths, unlike an unmodified resonator, accumulating the phases of successive wavelengths.
- This phase buildup be proportional to the distance, and the rate of change of wavelength selection, as shown by Fig. 1, and adds to the instantaneous selection according to equation (25).
- the instantaneous resonant mode of the cavity is also thus continuously activated, but as remarked, the cavity is not the final detector but a filter.
- the tank circuit of Fig. 9 which would act similarly, all but the instantaneous shifted frequency ⁇ get shorted to the ground.
- the foregoing analysis also shows that each shifted frequency does represent energy collected from across incoming frequencies.
- the present invention and its theory fill a basic gap m the quantum theory, as follows
- quantum mechanics the result of observing incoming radiation of unknown state ⁇ ) is defined to be one or more stationary states ( ⁇ of the receiver occurring with respective probability amplitudes ( ⁇ ) (see, for example, ⁇ 6 and ⁇ 10 of P A M Dirac's The Principles of Quantum Mechanics, Oxford, 4th edition, 1958)
- ⁇ probability amplitude
- Theorem 2 (Impossibility of stationarity) No physical state can be made perfectly stationary with finite measurements of finite resolution
- equation (13) f(r, t) — exp r) of equation (13), (41) where t denotes the local time at the receiver, and the scale factor a(t) ⁇ 1 + rH/c ⁇ 1 + HT, where r is the total path time.
- Eigenfunctions of the form of equation (41) were first described by L. Parker in the paper titled “Quantized fields and particle creation in expanding universe” , Physical Reviews, volume 183, number
- H refers to the Hubble expansion rate, the scale factor o, to the Friedmann-Robertson- Walker (FRW) metric, and the time-scale evolution in equations (39) and (41) to the cosmological time dilation (CTD) relative to our clocks.
- FRW Friedmann-Robertson- Walker
- CTD cosmological time dilation
- a as a refers to the observer's current local scale and is 1 identically at all times even when a is nonzero'
- ⁇ n 2 ⁇ Z 2 R A n ⁇ - A 771" (SI units), (45) where m e and q e denote the electronic mass and charge, respectively, and eo is the permittivity of vacuum. It is trivial to verify that all resulting ratios are invariant under the inventive modification.
- the grism (grating + prism) mode wavelength calibrations were performed by observing, in orbit, planetary nebulae Vy 2-2 and HB 12, while the inverse sensitivity curves were obtained by observing the white dwarf G191-B2B and G-dwarf P330E.
- this spectrometer is recalibrated while in orbit without ground based or ground-supplied physical referents, i.e. without using say a ground laser of known frequency with requisite gravitational redshift correction, or an onboard source of known spectrum.
- the calibrating observations are for sources at nontrivial astronomical distances, corresponding to source states and the shifted spectra of equation (12), in which r and H had been obtained from ground-based data so that ⁇ could be calibrated from the observed shifted frequencies ⁇ .
- equation (5) as applied in the creep hypothesis, the cause of the redshifts is independent of the incoming waves and their spectrum, hence by not using a local (i.e. ground or onboard) physical referent of wavelength, the procedure directly transfers the ground-determined HQ to the space-based observations! In prior physics, there had been no reason to expect any difference in redshifts between ground and nearby space.
- Onboard lamps are used for calibrating another of Hubble's instruments, the Space Telescope Imaging Spectroscope (STIS), but this is only useful for very low z objects.
- k ⁇ is a constant of proportionality
- ⁇ is the acting stress (tensor)
- n is an exponent having to do with the changing lattices formed by interaction between the dislocations
- Wp is the work function for breaking a single bond, typically of the order of 1 eV
- k ⁇ is the Boltzmann constant ( « 1.38 x ICT 23 J/K)
- T is the temperature of the lattice.
- the exponent n serves merely to account for the changing dislocation patterns over an extended range of stress, as commonly used in mechanical testing of materials. At the steady stresses and creep rates of concern in the hypothesis, n may be taken as 1, with the constant k ⁇ accounting for the applicable dislocation pattern. While the direction of the creep is dictated by ⁇ , its order of magnitude is determined principally by the last factor, which defines the probability of an individual dislocation as
- the spacecraft structures are made of rigid alloys that are much more resistant to creep at high stresses. For these likely reasons, among others, the possibility that creep could contribute to the anomalous data does not appear to have been examined at all by NASA, despite citing three manuscripts as mentioned.
- the creep rate would be smaller by a few orders, and dependent on the material properties and stress.
- the solid lattice is uniformly stretched along the instantaneous major principal axis of the tensor. This introduces elastic energy into the lattice: if the tidal tensor merely grew and ebbed without rotation, the stretching energy would return to the gravitating source with each ebb with no net effect on the lattice.
- Fig. 13 illustrates the tidal shrinkage that likely affects all of our ground and low-orbit telescopes and accounts for the Hubble redshifts via the principle of the present invention.
- every telescope [640] on earth [630] is subject to a steady compressive tidal stress due to the curvature of the earth's gravitational field, because the gravitational force vectors g at diametrically opposite points on the telescope objective must both point to the earth's centre of mass, and thus bear a tiny but nonzero compressive component of magnitude I ⁇ ⁇ 7g, where I is the diameter of the objective.
- WMAP Wilkinson microwave anisotropy probe
- CTD cosmological time dilation
- Fig. 14 illustrates the complementary phenomenon of tidal damage under expansive stress as a candidate offering detailed explanation of the anomalous data from Pioneer 10 and 11 missions.
- the creep hypothesis explains the variations in the anomaly seen over the life of Pioneer 10, as well as a slight difference in the residual values when the spacecraft were well beyond the solar planetary orbits.
- the main purpose of the spin stabilization was for keeping the spin axis [600] , and therefore the telemetry antenna, pointed towards earth, whereas the principal tidal force in deep space was that of the sun, so the tidal axis [602] subtended an angle a to the spin axis.
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CN113267799A (en) * | 2021-05-17 | 2021-08-17 | 重庆邮电大学 | Underwater quantum ranging method based on starlight quantum link transmission |
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