This application is a filing under 35 U.S.C. §371 of International Patent Application PCT/GB2010/000068, filed Jan. 18, 2010, which claims priority to Great Britain Application No. 0900746.9, filed Jan. 16, 2009.
This invention relates to a delay-line self-oscillator device.
Systems of electrical, electromagnetic or magnetic transmission-lines or ‘delay-lines’ (electrical, electromagnetic or magnetic transmission elements with a length that is at least a substantial fraction of the wavelength of the highest frequency component of an electrical, electromagnetic or magnetic signal that propagates along them) are found in various forms in engineering, scientific, and industrial instrumentation. Electrical delay-lines are in very widespread use; most commonly in the context of simple ‘interconnects’ i.e. channels to support communication between functional lumped electrical (or part-electrical) components. Apart from matching applications, the electrical properties particular to delay-lines are rarely exploited; indeed there is a widespread misconception that the incorporation of a section or sections of delay-line into an electrical system must be fundamentally deleterious to its overall performance. Moreover, the potential of certain electromagnetic and/or magnetic delay-line systems—in particular spin-wave delay-line systems—to form the basis of devices and systems with novel functionalities provided by their particular effective impedance properties remains largely unexplored.
Against this background, and in accordance with a first aspect of the present invention, there is provided a delay-line self oscillator as set out in claim 1.
Many electrical control and measurement instrumentation applications require long raw signal transmission line interconnects between an electrical ‘element’ and a set of driving electronics, for example due to the practical geometrical constraints of the engineering system. Embodiments of the present invention provide for the modal characteristics of electrical delay-lines to be exploited for a wide range of instrumentation applications, and provide a means to enhance the achievable functionality and/or performance of the instrumentation without the need for expensive additional electrical hardware or electronics.
Further embodiments of the present invention operating in conjunction with electromagnetic or magnetic delay-line systems provide for closed-loop electromagnetic or magnetic instrumentation systems—for example spin-wave self-oscillator systems—with novel functionalities.
Further features and advantages of the present invention will be apparent from the appended claims and the following description.
In their most general sense, embodiments of the present invention provide an electrical, electromagnetic or magnetic delay-line arrangement connected to an oscillator control circuitry, which employs positive feedback, so as to form a resonant system referred to henceforth as a Delay-Line Self-Oscillator. The resonant system (which includes the delay-line arrangement) is self-excited at a, or one of a number of, resonance or anti-resonance frequency/frequencies by a driving signal from the control circuitry. The delay-line arrangement may operate in any region of the electromagnetic or magnetic spectrum, for example: it may comprise a section or sections of electrical transmission line of the sort commonly employed as signal interconnects in analogue and digital signal processing systems operating at radio and microwave frequencies, or it may be a magnetic structure (for example a thin-film ferro- or ferri-magnetic waveguide) which supports the propagation of linear or non-linear spin-wave (magnetic) excitations.
Delay-Line Self-Oscillators (DLSOs) of the type described herein are examples of distributed-parameter electrical, electromagnetic or magnetic oscillators. Specifically, the DLSOs of the type referred to herein each have an operating frequency and/or quality factor (Q) that is influenced to a determinable amount by the frequency response and loss characteristics of a delay-line arrangement. The delay-line arrangement comprises at least one delay-line and may incorporate other functional active or passive electronic, electromagnetic or magnetic components—‘electrical, electromagnetic or magnetic elements’. A delay-line as defined in the present context is an electrical, electromagnetic or magnetic transmission element with a characteristic dimension that is at least a substantial fraction of the wavelength of the signal that propagates along it. Many realizations of delay-lines are possible in the present context; for example, a delay-line may comprise a length of coaxial transmission line, an electrical or magnetic waveguide, or a path in free space etc.
Any delay-line may be described in terms of an effective length l, effective characteristic impedance (defined as the ratio of two quantities conserved across line interfaces):
and effective propagation coefficient:
Here, R0, L0, G0 and C0 are respectively the effective per-unit length resistance, inductance, shunt conductance and shunt capacitance of the delay-line, vp is the phase velocity along it, ω the frequency of excitation and α a loss coefficient. An electrical, electromagnetic or magnetic element forming part of a ‘delay-line arrangement’ in the present context is defined as any electrical, electromagnetic or magnetic system or component that is separated from the DLSO control circuitry 30 by at least one section of delay-line. Depending on the requirements of the DLSO (i.e. the application of the technology), the frequency of the driving signal (i.e. the operating frequency of the DLSO) may be substantially dependent upon or substantially independent of changes in the characteristics of certain electronic, electromagnetic or magnetic components or sections of delay-line forming part of the delay-line arrangement.
In general, delay-line arrangements encompassed by embodiments of the present invention exhibit input/output phase responses which vary continuously with frequency over some finite bandwidth. A given delay-line arrangement has an effective frequency dependent input impedance Zin(jω). The magnitude of the frequency response of the input impedance |Zin(jω)| features minima and maxima. Minima correspond to resonance frequencies, maxima to anti-resonance frequencies of the delay-line arrangement. The exact form of the input impedance of the delay-line arrangement is dependent on the detail of the system (i.e. multiplicity, type and arrangement of electrical, electromagnetic or magnetic element(s) and delay-line(s) incorporated).
The principles underlying the delay-line arrangement encompassed by embodiments of the present invention may be better understood by consideration of a single electrical delay-line terminated by a load ZL(jω). ZL(jω) may take any real, imaginary or complex value including zero and infinity (i.e. the delay-line may have any terminating impedance including open or short-circuit).
where symbols are as defined in (1) and (2) above.
For the purposes of illustration the frequency response characteristics of a particular electrical implementation of the delay-line arrangement in
which is purely real and frequency independent. Additionally, when these conditions are met, the loss coefficient α of (2) is approximately zero (i.e. γ=jβ) and thus (3) may be approximated by
For such an arrangement with the parameter values shown in Table 1,
The optional frequency counter 80 and peak detector 90 provide for signal processing/capture if appropriate. The frequency counter 80 permits provision of a frequency output. The peak detector (or demodulator) 90 may additionally or alternatively provide an output indicative of the level of oscillation of the delay-line arrangement 20. Equally, the DLSO 10 may be incorporated into a control, instrumentation or signal processing system where no such outputs are desirable.
During a transient start-up period the control circuitry 30 commences oscillation. Noise initiated oscillations are received by the amplifier 50, amplified, processed by the amplitude controller (N-LACE) 70, the specific details of which are set out below, and fed back to the delay-line arrangement 20 via Z(jω) 40. Once the start-up period has passed, constant amplitude oscillation is established. The combination of the delay-line arrangement 20, Z(jω) 40 and the control circuitry 30 are arranged in such a way as to promote stable, robust oscillation of the closed-loop system. Particularly, the frequency selection impedance Z(jω) 40 has a certain frequency-dependent magnitude and/or phase shift which provides modal selectivity. Again this will be explained further below. The frequency selection impedance may operate in the electrical, electromagnetic or magnetic domains.
A theoretical analysis of the DLSO described above is set out in Appendix A for the sake of completeness. This Appendix also describes the conditions required for stable, sustained operation of any DLSO in accordance with the present invention.
Appendix A describes the characteristics of the N-LACE 70 by treating the DLSO 10 in terms of an entirely electrical equivalent two terminal electrical circuit, as shown in
In this representation, the control circuitry 30 incorporating the non-linear amplitude control element (N-LACE) 70 may be modelled by a shunt conductance GC as depicted in
For the purposes of analysis, it is useful to consider functionality of the non-linear amplitude control element (N-LACE) 70 separately from that of the rest of the circuitry of the control circuitry 30. The model of
The function of the non-linear amplitude control element (N-LACE) 70 is to provide an amplitude regulated feedback signal i(t) to drive the delay-line arrangement 20. In general terms, the N-LACE 70 provides gain and non-linearity. There are several ways in which this can be achieved, although as will be seen, some of these are more preferred than others since they provide for optimized performance of the DLSO 10.
The output of the delay-line arrangement 20—v1(t) (FIG. 4C)—is a continuous periodic energy signal. The signal v1(t) has a spectral component s(t) at the operating frequency ω0 of the DLSO 10. The time-period T characteristic of s(t) is given accordingly by:
The signal s(t) is isolated from v1(t) (e.g. by filtering and subsequent phase-compensation) so that the signal arriving at the input to the N-LACE 70 is of the form
v(t)=As(t−τ1), (7)
where A is a constant and τ1 a time-constant to account for inherent or imposed time delay and/or phase shift in the signal path. The feedback signal generated by the N-LACE 70 in response to v(t) is of the form:
i(t)=aNL(v(t−τ2)). (8)
where
τ2=τ1+τ. (9)
and τ is a time delay characteristic of the input-output conversion in the N-LACE 70 which may or may not be frequency dependent. The instantaneous dynamic gain of the N-LACE 70 is defined for any instantaneous signal input v(t1).
In the most general implementation of the DLSO 10, the function aNL(v(t)) which describes the N-LACE 70 is an arbitrary non-linear function. However, in preferred embodiments of the N-LACE 70, the function aNL(v(t)) has particular advantageous characteristics. From henceforth, a non-linear amplitude control element with such particular advantageous characteristics will be referred to as an optimal non-linear amplitude control element or oN-LACE. The characteristics of such an oN-LACE will now be described.
When at time t1 the instantaneous amplitude of the oN-LACE input signal v(t1) is between certain preset fixed ‘positive’ and ‘negative’ thresholds the corresponding output i(t1+τ) of the oN-LACE 70 is approximately equivalent to a linear amplifier with a gain that is—in the most general case—dependent on the polarity of the signal. For a given oN-LACE implementation, the ‘positive’ and ‘negative’ thresholds are respectively
where B1, B2 are any real, non-negative integers (so long as in a given realization either B1 or B2 is non-zero) and K01 and K02 are real non-zero positive integers equal to the small-signal (SS) dynamic gains for positive and negative v(t) respectively:
In this signal regime, the output of the oN-LACE 70 is described by:
i(t1+τ)=K01v(t1) for sgn{v(t1)}=1,
i(t1+τ)=K02v(t1) for sgn{v(t1)}=−1. (12)
Note that the relative polarities of the oN-LACE input and output signals are arbitrarily defined. In the most preferred embodiment of the oN-LACE 70, at least one of K01 and K02 is a large, positive, real constant. Equation (12) describes the ‘quasi-linear amplification regime’ or ‘small-signal amplification regime’ of the oN-LACE 70.
If at time t1 the instantaneous amplitude of v(t1) is positive and its magnitude equals or exceeds the threshold
and/or the instantaneous amplitude of v(t1) is negative and its magnitude equals or exceeds the threshold
the oN-LACE 70 operates in a ‘strongly non-linear’ or ‘large-signal’ regime. In the most preferred embodiment of the oN-LACE 70, the dynamic gain in the large-signal (LS) regime is zero regardless of the polarity of the signal v(t1):
In a general embodiment of the oN-LACE, the large-signal dynamic gain gdLS(t) is approximately zero regardless of the polarity of the signal v(t1) i.e:
The most preferred embodiment of the optimal non-linear amplitude control element features a large-signal regime in which the amplitude of the oN-LACE output i(t1+τ) takes a constant value +B1 if at time t1 the instantaneous amplitude of v(t1) is positive and a constant value −B2 if the converse is true. This behaviour is summarized by:
In the special case that B1=B2=B and K01=K02=K0, (14) becomes:
and a symmetrical oN-LACE input signal v(t1) results in a symmetrical output function i(t1+τ).
Between the quasi-linear and strongly non-linear signal regimes of the oN-LACE there is a ‘transitional’ signal region or ‘transition region’ (T). In this region, the behaviour of the non-linear amplitude control element is neither quasi-linear nor strongly non-linear. In the most preferred embodiment of the oN-LACE the transition region is negligibly wide.
Three key features of the oN-LACE are: Feature 1: a sharp transition between the quasi-linear (small-signal) and strongly non-linear (large-signal) regimes effected by the instantaneous signal magnitude |v(t1)| exceeding a pre-determined threshold the value of which may or may not be dependent on the polarity of the signal (c.f. (14), (15)); Feature 2: a narrow and preferably negligibly wide transitional signal regime; Feature 3: approximately instantaneous transition between quasi-linear and strongly non-linear regimes. Feature 3 is equivalent to the oN-LACE 70 having capacity to respond to changes in the amplitude (and frequency) of the instantaneous input signal v(t1) on a timescale typically significantly shorter than the characteristic signal period T i.e the oN-LACE 70 has a certain amplitude temporal resolution Δτ<<T. Furthermore, with a particular implementation of the oN-LACE described in the context of the present invention, it may be arranged that the instantaneous amplitude of the oN-LACE output i(t1) corresponds approximately instantaneously to that of the input i.e. if desirable, it may be arranged that the time-constant τ defined in (9) is negligibly small. Alternatively and more generally, the oN-LACE 70 is designed such that a certain known time-delay τ (which may or may not be frequency dependent) exists between oN-LACE input and corresponding output; in such a system an oN-LACE input v(t1) gives rise to an output i(t1+τ) with amplitude temporal resolution Δτ independent of τ. It is an important and particular feature of the present invention that the amplitude control achieved via the oN-LACE 70 is not of a slow-acting ‘averaging’ type. Moreover, changes in the centre frequency or dominant frequency component of the input signal v(t1) may be resolved on a time-scale comparable with the amplitude temporal resolution Δτ; i.e. the frequency content of a general output signal i(t1+τ) corresponds to the instantaneous frequency content of the input v(t1).
The input-output signal characteristics of the oN-LACE 70 are now considered, for the special case that the input is a symmetrical, sinusoidal waveform with frequency ω0 and period of oscillation T (6). Asymmetrical input signals are described subsequently. With reference to (8) and (9) and the analysis there, it is assumed that the oN-LACE input signal v(t+τ1) is a time-shifted, linearly amplified derivative of a signal s(t): a monochromatic signal at the operating frequency of the DLSO 10, ω0. For clarity in this section all signals are referenced relative to time t defined by s(t):
s(t)=a sin ω0t, (16a)
v(t+τ1)=A sin ω0t. (16b)
The oN-LACE input signal (16b) is depicted in
In the quasi-linear amplification regime, the output signal from the oN-LACE 70 is given by a time-shifted, linearly amplified version of the input signal:
i(t+τ2)=AK0 sin ω0t. (17)
i.e. the oN-LACE 70 operates continuously in the quasi-linear amplification regime.
The function of the oN-LACE 70 is to amplify the received monochromatic energy signal v(t+τ1) at ω0 (in general an amplified, time-shifted, phase compensated version of a raw signal s(t)), and redistribute its RMS power over harmonics of the signal frequency ω0. The Fourier series describing the oN-LACE input and output signals may be analysed to give an insight into how the distribution of power is affected by the amplitude A of the input signal v(t+τ1). In particular a Fourier representation of the output signal of the oN-LACE may be derived, which corresponds to a symmetrical sinusoidal input of general amplitude A assuming oN-LACE characteristics as described above.
i.e. for the positive half-cycle
whilst for the negative half-cycle
The constant B and angle α are related by
For all possible values of AK0, the periodicity and symmetry of i(t+τ2) are preserved. Thus the Fourier series describing i(t+τ2) is of the form
For constant B and increasing AK0, the fraction α decreases and i(t+τ2) tends to a square wave with fundamental frequency component ω0.
Whilst the total power is the summation
The summation (22) has a finite limit:
P=2B2. (23)
Thus as AK0→d where d>>B and α→0, the ratio P0/P tends to a finite limit S1:
The Fourier analysis above may be extended to input waveforms of lower symmetry. For the purposes of illustration the simple asymmetric input function depicted in
In the limit of large AK0—i.e. in the large-signal regime—i(t+τ2) tends to an asymmetric square wave with fundamental frequency component ω0 as depicted in
For the limiting case as AK0→d where d>>B and α→0, the power in the signal i(t+τ2) at the fundamental frequency ω0 is given by
To summarize the properties of the optimal non-linear amplitude control element that is preferably employed in the DLSO 10 of embodiments of the present invention, it features three distinct signal regimes: a small-signal or quasi-linear regime (SS), a transitional signal regime (T) and a large-signal strongly non-linear regime (LS). In assessing the performance of a general non-linear amplitude control element 70 there are four key parameters to consider:
I. The small-signal dynamic gain at time t1:
where τ is a time delay characteristic of the input-out conversion in the N-LACE 70, which may or may not be frequency dependent.
II. The linearity of the small-signal quasi-linear regime.
III. The width of the transitional regime (T)—i.e. the range of input signal amplitudes for which the oN-LACE response would be described as transitional.
IV. The large-signal dynamic gain at time t1:
where τ is as previously defined.
In the most preferred embodiment of the oN-LACE 70, the control circuitry dynamic gain (I) takes a large constant value which may or may not be dependent on the polarity of the input signal (12); the small-signal quasi-linear signal regime is approximately entirely linear (II), the transitional regime (T) (III) is so narrow as to be negligible, and the large-signal dynamic gain (IV) is zero.
The family of non-linear amplitude control element input-output characteristics that fall within the oN-LACE definition are illustrated in
Other oN-LACE input-output characteristics are possible that are less favourable than the ideal characteristic of
In a particular realization of the oN-LACE using analogue semiconductor components (such as is shown in
In the most general sense, there are two different ways in which non-linear amplitude control functionality may be achieved. The first type of non-linear amplitude control incorporates a discrete active element or an arrangement of discrete active elements which may be electrical, electromagnetic or magnetic in nature and which provide a negative differential conductance or transconductance (ie, gain) and a non-linearity. The non-linearity, and, in the majority of cases part or all of the gain, are each provided by a physical, non-linear process which is an inherent property of one or more of the active elements.
The functionality of the second type of non-linear amplitude controller is entirely equivalent to that of the first, but here, the non-linearity is provided not by an inherent physical non-linear process, but by deliberately arranging active elements so that the desired non-linear behaviour is promoted. One way of doing this is, for example, to exploit the gain saturation of an operational amplifier, or to use a transistor pair, as exemplified in
In both types of non-linear amplitude controller, the provision of gain and the provision of non-linearity may be considered as two independent functional requirements, which might accordingly be provided by two distinct functional blocks. In practice, the gain-non-linearity combination is often most readily achieved by exploiting the properties of a single collection of components. In any event, at least conceptually, the non-linearity may be considered as being superimposed on top of a linear gain characteristic, to create the desired set of input-output characteristics.
Considered in this way, the key function of the non-linearity is then to limit the maximum value of the gain (or the transconductance, or simply the output signal) of the overall amplitude regulator circuitry. Overall, the intention is that the combination of the “gain” functionality and the “non-linear” functionality provides a unit which delivers a significant gain for small signals, that has a constant magnitude output once the input exceeds a pre-determined threshold, as explained above.
Looking first at
The collector of the first transistor T1 is capacitively coupled to a delay-line arrangement 20. Thus the circuit of
The collector of the second transistor T2 provides a second circuit output to the peak detector/demodulator 90 (see
In each case of the circuit arrangements of
In each of the circuits of
Having set out the principles underlying embodiments of the present invention, some examples of practical devices employing these principles will now be described.
Any delay-line arrangement operating in the electrical, electromagnetic or magnetic domain may be reduced to an equivalent two-port electrical network (or arrangement of such networks). The voltage and current, or effective voltage and current at any point along a delay-line arrangement 20 comprising at least one delay-line is conveniently described using transfer function matrices. Such transfer function matrices may be manipulated either by hand or by computer using a numerical technique in order to solve for the resonance and anti-resonance frequencies of a given delay-line arrangement 20.
In the alternative system of
A given implementation of the DLSO is designed to exploit the frequency response characteristics of a given delay-line arrangement 20 (e.g.
Any combination of delay-line arrangement 20 and frequency selection impedance embodying the present invention may be described in terms of an effective impedance Zin(jω) presented to the control circuitry 30. Implementations of the DLSO 10 divide into two categories: Type A DLSOs are designed to operate the delay-line arrangement 20 at one of its characteristic resonance or anti-resonance frequencies i.e. one of the frequencies at which the magnitude of the effective input impedance Zin(jω) is either minimum or maximum. Type B DLSOs are designed in such a way as to operate the delay-line arrangement 20 which is at a frequency neither co-incident with a characteristic resonance frequency of the delay-line arrangement 20 nor co-incident with an anti-resonance frequency of the delay-line arrangement but instead co-incident with some other resonance or anti-resonance frequency determined by the combination of the delay-line arrangement 20 effective input impedance Zin(jω) and the frequency selection impedance Z(jω) (e.g. a resonance frequency of a combined system comprising the delay-line arrangement 20 and the frequency selection impedance Z(jω)).
Typically Zin(jω) is characterised by not one but a multiplicity of resonance frequencies. Thus there is required in Type A realizations of the DLSO 10 a means to select a ‘strongly-preferred mode’—i.e. to promote robust operation of the DLSO 10 at a single particular resonance or anti-resonance frequency. In Type B realizations of the DLSO 10 there is furthermore required a means to promote operation of the DLSO 10 at some single advantageous resonance or anti-resonance frequency ωB. In both Type A and Type B DLSOs, modal selectivity may be achieved by several techniques. Two such techniques are discussed below.
Modal Selectivity Via Frequency Selection Impedance or Frequency Selection Impedance Stage Design
In this technique modal selectivity is achieved by combining an appropriately designed frequency selection impedance with a given delay-line arrangement 20.
obeys
where r is the loss equivalent resistance presented by Zin(jω). Accordingly a figure of merit may be defined:
f(jω)=Z3(jω)(Z3(jω)+Z2(jω)). (30)
If there are a number of possible operating modes defined by the frequency response characteristics of Zin(jω) which satisfy (29), the modes corresponding to the highest positive value of f(jω) will be favoured. Moreover, since the transconductance gm and r are necessarily a positive quantities, certain modes may be excluded entirely by for example, selecting a combination of Z2(jω) and Z3(jω) such that f(jω) has a negative value at these frequencies.
for viable amplitude-stable self-oscillation is
and thus the figure of merit in this case is given by
f(jω)=Z12(jω). (32)
The system of
As a further illustration, the characteristics of a particular implementation of the scheme of
The dotted lines in
Modal Selectivity Via Variable Loop Gain
This alternative mode-stabilization technique is illustrated schematically in
As explained above, the particular form of the delay-line arrangement 20, frequency selection impedance and control circuitry 30 may be designed in such a way as to optimize a given DLSO 10 for a particular application. Particular properties of a variety of specific DLSOs will accordingly now be described.
‘Time-of-Flight Systems’
DLSOs 10 incorporating a delay-line arrangement 20 featuring one or more delay-lines 200, 200a, 200b connected to the control circuitry 30 in a ‘loop’ type system have operating frequencies substantially determined by the characteristic length of the incorporated delay-line or lines and thus may be regarded as ‘time-of-flight’ type DLSOs. Time-of-flight arrangements operating in conjunction with electrical delay-line arrangements feature excellent immunity to microphonic noise, whilst time-of-flight DLSOs incorporating spin-wave (magnetic) delay-line arrangements have applications in—for example—sensing, information processing and data storage.
Many such time-of-flight type DLSOs are possible.
Design for Optimal Sensitivity or Optimal Insensitivity
A DLSO may be realized in conjunction with a given delay-line arrangement 20 such that the properties of the oscillator (operating frequency and/or amplitude of oscillation) are substantially sensitive or substantially insensitive to change or changes in the properties of electrical, electromagnetic or magnetic elements that form part of the delay-line arrangement 20. The realization of an optimally sensitive or optimally insensitive DLSO 10 (and the extent to which an optimally sensitive or insensitive DLSO 10 is viable within practical constraints) depends on the requirements and constraints presented by the delay-line arrangement and overall required function of the DLSO.
It has been established that the impedance Zin(jω) presented by a given delay-line arrangement 20 exhibits minima and maxima—i.e. there are featured both resonance and anti-resonance frequencies. When operated at one of its characteristic resonance frequencies, the delay-line arrangement presents a small or very small effective (electrical, electromagnetic or magnetic) impedance to the control circuitry 30 whilst if operated at one of its anti-resonance frequencies, the effective impedance presented is large or very large. In general, a DLSO 10 may be realized that embodies the present invention, which is both substantially mode-stable and substantially sensitive to changes in impedance of a given delay-line arrangement (and therefore for example, changes in the impedance of constituent electrical, electromagnetic or magnetic elements) if the delay-line arrangement presents a small effective impedance. Conversely, if the effective impedance presented by the delay-line arrangement is very large, it may be arranged that the DLSO is substantially non-mode stable and substantially insensitive to changes in the properties of the delay-line arrangement. Thus in the context of the present invention, the choice of whether to operate the delay-line arrangement at, or proximal to one of its resonance frequencies or at or proximal to one of its anti-resonance frequencies is dependent on the sensitivity and stability requirements of the instrumentation system.
In certain DLSO implementations, sensitivity is further dependent on the impedance relationship between the delay-lines and incorporated electrical, electromagnetic or magnetic element or elements and the relationship or relationships between the effective overall effective quality factor of the delay-line arrangement Qe, the effective quality factor or quality factors QL of the electrical, electromagnetic or magnetic element or elements (where these can be defined) and the unloaded effective quality factor or effective quality factors of the incorporated delay-line or delay-lines Q.
Design for Minimal Interaction in Multiple Oscillator Networks
By realizing DLSOs—DLSOs 1 and 2—with independent delay-line arrangements: respectively delay-line arrangements 1 and 2, such that the operating frequency of DLSO 1, ω1 is co-incident with or proximal to a resonance frequency of delay-line arrangement 1 whilst being co-incident with or proximal to an anti-resonance frequency of delay-line arrangement 2 and vice-versa i.e. the operating frequency of DLSO 2, ω2 is co-incident with or proximal to a resonance frequency of delay-line arrangement 2 whilst being co-incident with or proximal to an anti-resonance frequency of delay-line arrangement 1, the two DLSOs may be made substantially independent. Many possible methods of arranging this condition are possible and the technique may be extended to large networks of ‘switched-mode’ DLSOs (see below). A simple illustrative example of such an arrangement is two DLSOs both incorporating electrical delay-line arrangements of the type shown in
An alternative method of interaction minimization in multiple DLSO systems realized in embodiments of the present invention involves operating n DLSOs 10 in conjunction with n corresponding delay-line arrangements at differing frequencies ωn and designing the control circuitry 30 such that for i=1 . . . n the ith DLSO 10 rejects all signals (electrical, electromagnetic or magnetic or a combination of these) apart from those corresponding to n=i. This may be achieved by incorporating a filter element (which may for example take the form of a bandpass or notch filter) in each DLSO 10 which filters the signal received from the delay-line arrangement prior to amplitude regulation and feedback. A phase compensating element may also be included to compensate for unwanted signal phase-shifts brought about by the presence of such a filtering element.
Design for Noise or Signal Resection
The principles detailed herein allow for the realization of DLSOs or systems of such oscillators substantially insensitive to a known electrical, electromagnetic or magnetic noise or signal source at a particular frequency. Insensitivity is achieved by arranging that the delay-line arrangement 20 particular to the DLSO or DLSOs presents a large effective impedance to an appropriately designed arrangement of control circuitry 30 if excited at the frequency or frequencies at which the noise or signal(s) occur whilst presenting a small effective impedance at the desired operating frequency. Alternatively such immunity may be achieved by a filtration technique e.g. the unwanted signal may be filtered out, or a signal at the desirable operating frequency preferentially amplified prior to the main amplification and amplitude regulation part of the DLSO control circuitry 30. In DLSOs where such a filtering element is present, a phase compensating element may be included to compensate for unwanted signal phase-shifts.
Design for Maximal Interaction in Multiple Oscillator Networks
In certain applications it may be desirable to realize a network or system of DLSOs which interact strongly with each other. For example, it may be required that one or more slave DLSOs operate in synchrony with a single master oscillator.
By realizing oscillators—oscillators 1 and 2—with independent delay-line arrangements 20: respectively delay-line arrangements 1 and 2, such that the operating frequency of oscillator 1, ω1 is co-incident with or proximal to a resonance frequency of delay-line arrangement 1 and co-incident with or proximal to a resonance frequency of delay-line arrangement 2 and vice-versa i.e. the operating frequency of oscillator 2, ω2 is co-incident with or proximal to a resonance frequency of delay-line arrangement 2 and co-incident with or proximal to an resonance frequency of delay-line arrangement 1, the two DLSOs may be made substantially dependent. Many possible methods of arranging this condition are possible and the technique may be extended to large networks of continuous or ‘switched-mode’ DLSOs. A trivial example of such an arrangement is a system or network of two or more identical DLSOs operating at the same frequency. More sophisticated systems operate non-identical DLSOs at differing, advantageous frequencies.
An alternative method of interaction maximization in multiple DLSO systems realized embodying the present invention involves operating n DLSOs in conjunction with n corresponding delay-line arrangements 20 at frequencies ωn and designing the control electronics such that for i=1 . . . n the ith DLSO is responsive to signals from all others, or from selected others. This may be achieved by incorporating a filter element (which may for example take the form of a bandpass or notch filter operating in the electrical, electromagnetic or magnetic domain) in each DLSO which filters the signal received from the delay-line arrangement prior to amplitude regulation and feedback. A phase compensating element (operating in the electrical, electromagnetic or magnetic domain) may also be included to compensate for unwanted signal phase-shifts brought about by the presence of such a filtering element.
Design for Noise or Signal Sensitivity
The principles set out herein allow for the realization of DLSOs or systems of such oscillators substantially sensitive to a known electrical, electromagnetic or magnetic noise or signal source at a particular frequency. Sensitivity is achieved by arranging that the delay-line arrangement particular to the DLSO or DLSOs presents a small effective impedance to the control circuitry 30 if excited at the frequency or frequencies at which the noise or unwanted signal occur. Alternatively such sensitivity may be achieved by incorporation of an additional, frequency dependent gain (in the electrical, electromagnetic or magnetic domain) into the DLSO control circuitry 30 prior to the main amplification and amplitude regulation part of the control circuitry 30. In DLSOs where such a frequency dependent gain is present, a phase compensating element (operating in the electrical, electromagnetic or magnetic domain) may be included to compensate for unwanted signal phase-shifts. Such systems may be useful in applications where there is a requirement for a sensitive, highly frequency selective detector.
Design for Maximal/Minimal Interaction in Oscillator Networks
A combination of the techniques above may be used to realize networks or arrays of DLSOs in which the interaction or lack of interaction between particular oscillators is determined by the design of the control circuitry 30, frequency selection impedance 220 and delay-line arrangement 20 of each DLSO.
Modes of Operation
DLSOs embodying the present invention may be operated continuously or in a pulsed or ‘burst’ mode—i.e. for short periods of time. Alternatively or additionally DLSOs may be realized in which a single set of circuitry representing the control circuitry 30 is used in conjunction with multiple electrical, electromagnetic or magnetic elements or delay-line arrangements 20. The DLSO may be such that a single element or delay-line arrangement 20 is operative at any one time—i.e. one of several delay-line arrangements or one of several electrical, electromagnetic or magnetic elements in conjunction with a given delay-line or arrangement of delay-lines are switched into operation electrically, magnetically, thermally, mechanically, optically or otherwise at any one time. Such switching may involve electrical or magnetic changes at the control circuitry 30 and/or the delay-line or delay-lines and/or the electrical, electromagnetic or magnetic element or elements and/or the delay-line arrangements 20. The operating frequencies particular to each delay-line arrangement 20 in such a DLSO may be the same or different.
In a further embodiment of the DLSO the frequency selection impedance or impedance stage (operating in the electrical, electromagnetic or magnetic domain) may be locally or remotely controlled. Such local or remote control may be electrical, magnetic, thermal, mechanical, optical, hydraulic etc. and may be such that the behaviour of the DLSO 10—for example the operating frequency—is dependent on this control.
In a further implementation of the DLSO, the operating mode may be controlled by an element or elements sensitive to some external stimulus such that the operating frequency of the DLSO is determined by this stimulus and in response to certain changes in this stimulus a step-wise change in the operating frequency of the DLSO is observed. The sensitive element or elements that determine the operating mode may be incorporated into the control circuitry 30 or may form part of the delay-line arrangement 20.
Delay-Lines Defined by Regions of Low Conductivity Media
As established above, the DLSOs that embody the present invention may be realized in conjunction with delay-line arrangements 20 comprising or incorporating a delay-line or delay-lines defined by a region of free space or other low-conductivity transmission medium. This concept is illustrated schematically in the example system of
Although a specific embodiment of the present invention has been described, it is to be understood that various modifications and improvements could be contemplated by the skilled person.
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0900746.9 | Jan 2009 | GB | national |
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PCT/GB2010/000068 | 1/18/2010 | WO | 00 | 9/13/2011 |
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WO2010/082036 | 7/22/2010 | WO | A |
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Number | Date | Country | |
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20110316638 A1 | Dec 2011 | US |