AU2007211882B2 - Modulation signals for a satellite navigation system - Google Patents

Modulation signals for a satellite navigation system Download PDF

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AU2007211882B2
AU2007211882B2 AU2007211882A AU2007211882A AU2007211882B2 AU 2007211882 B2 AU2007211882 B2 AU 2007211882B2 AU 2007211882 A AU2007211882 A AU 2007211882A AU 2007211882 A AU2007211882 A AU 2007211882A AU 2007211882 B2 AU2007211882 B2 AU 2007211882B2
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signal
subcarrier
boc
phase
code
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John Ivor Rewbridge Owen
Anthony Richard Pratt
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UK Secretary of State for Defence
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Description

AUSTRALIA Patents Act 1990 COMPLETE SPECIFICATION Standard Patent Applicant(s): SECRETARY OF STATE FOR DEFENCE Invention Title: MODULATION SIGNALS FOR A SATELLITE NAVIGATION SYSTEM The following statement is a full description of this invention, including the best method for performing it known to me/us: MODULATION SIGNALS AND METHOD This patent application is a divisional application of Australian patent application 2004268254 and relates to subject matter disclosed in that application. Some description of the invention of 5 2004268254 is included herein to facilitate understanding of the present invention. If necessary reference may be had to the disclosure of application 2004268254 to understand the present invention, and the disclosure of that application is incorporated herein by reference. Field of the Invention The invention relates to modulation signals, systems and methods such as, for example, navigation and positioning signals, systems and methods. 10 Background to the invention Satellite Positioning Systems (SPS) rely on the passive measurement of ranging signals broadcast by a number of satellites, or ground-based or airborne equivalents, in a specific constellation or group of constellations. An on-board clock is used to generate a regular and usually continual series of events, often known as 'epochs', whose time of occurrence is coded into a random or pseudo-random code 15 (known as a spreading code). As a consequence of the pseudo-randon or random features of the time epoch encoding sequence, the spectrum of the output signal is spread over a frequency range determined by a number of factors including the rate of change of the spreading code elements and the waveform used for the spreading signal. Typically, the spreading waveform is rectangular and has a sine function power spectrum. 20 The ranging signals are modulated onto a carrier signal for transmission to passive receivers. Applications are known that cover land, airborne, marine and space use. Typically, binary phase shift keying is employed to modulate the carrier signal, which, itself, has a constant magnitude. Usually, at least two such signals are modulated onto the same carrier in phase quadrature. The resulting carrier signal retains its constant envelope but has four phase states depending upon the two independent 25 input signals. However, it will be appreciated that two modulating signals do not need to have the same carrier magnitude. It is possible for a constant carrier magnitude of the combined signal to be maintained by appropriate selection of corresponding phases other than n/2 radians. An example of such a satellite positioning system is the Global Positioning System (GPS). Generally, the GPS operates using a number of frequencies such as, for example, LI, L2 and L5, which are 30 centred at 1575.42 Ml-lz, 1227.6 MHi and 1176.45 Mz respectively. Each of these signals is modulated by respective spreading signals. As will be appreciated by those skilled in the art, a Coarse Acquisition (CA) code signal emitted by the GPS Satellite Navigation System is broadcast on the LI N \Mlcboume\Case\Pate\60000-60 99 \P6001 7 AU I\Specis\P60037 AU I Spcification 2007-8-3 doc 7/08/07 frequency of 1575.42MHz with a .spreading code rate (chip rate) of 1.023MHz. The CA has a rectangular spreading waveform and is categorised as BPSK-RI. The GPS signal structure is such 5 that the signal broadcast by the satellites on the Li frequency has a second component in phase quadrature, which is known as the precision code (P(Y) code) and is made available to authorised users only. The P(Y) signal is BPSK modulated with a spreading code at 10.23MHz with a magnitude which is 3dB lower in signal power than the CA code transmission. Consequently, the Q component la . has a magnitude-which is 0.7071 (-3dB) of the magnitude of the I component. It will be appreciated by those skilled in the art that the phase angles of these states of these signals are ±35.265* in relation to the ±I axis (phase of the CA code signal as specified in ICD GPS 200C). One skilled in the art also appreciates that the P code is a function of or is encrypted by the Y code. The Y code is used to encrypt the P code. One skilled in the art appreciates that the LI signal, containing both I & Q components, and the L2 signal can be represented, for a given satellite, i, as SL,(t)= App,(t)d,(t)cos(ait)+ Acc,(t)d,(t)sin(wit), and SL(t) = B~p,(t)d,(t)cosCt 2 t) where Ap and Ac are the amplitudes of the P and CA codes, typically Ap=2Ac; Bp is the amplitude of the L2 signal; ca and (2 are the L1 and L2 carrier frequencies; pi(t) represents the P(Y) ranging code and is a pseudo-random sequence with a chip rate of 10.23 Mcbps. The P code has a period of exactly 1 week, taking values of +1 and -1; ci(t) represents the CA ranging code and is a 1023 chip Gold code, taking values of +1 and -1; di(t) represents the data message, taking values of +1 and -1. A satellite constellation typically comprises 24 or more satellites often in similar or similarly shaped orbits but in a number of orbital planes. The transmissions from each satellite are on the same nominal carrier frequency in the case of code division access satellites (such as GPS) or on nearby related frequencies such as GLONASS. The satellites transmit different signals to enable each one to be separately selected even though several satellites are simultaneously visible. The signals from each satellite, in a CDMA system like GPS, are distinguished from each one another by means of the different spreading codes and/or differences in the spreading code rates, that is, the pi(t) and cj(t) sequences. Nevertheless, as will be appreciated from the power spectrum 100 shown in figure 1 there remains significant scope for interference between the signals transmitted by the satellites. Figure 1 shows power spectra 100 for the CA and P(Y) codes. The power spectrum 102 for the CA code has maximum power. at the carrier frequency Ll and zeros at multiples of the fundamental frequency, 1.023MHz, of the CA code. For example, it can be appreciated that zeros occur either side of the carrier frequency at ±1.023MHz, ±2.046MHz etc. Similarly, the power 2 spectrum 104 for the P(Y) code has a maximum amplitude centred on the L I and L2 frequencies, with zeros occurring at multiples of ±10.23MiHz as is expected with a sinc function waveform. It is known to further modulate the ranging codes using a sub-carrier, that is, a further signal is convolved with the P codes and/or CA codes to create Binary Offset Carrier (BOC) modulation as is 5 known within the art see, for example, J. W. Betz, "Binary Offset Carrier Modulation for Radionavigation", Navigation, Vol. 48, pp2 2 7- 24 6 , Winter 2001-2002. Standard BOC modulation 200 is illustrated in figure 2. Figure 2 illustrates the combination of a portion of a CA code 202 with a subcarrier signal to produce the BOC signal 204 used to modulate a carrier such as, for example, Li. It can be appreciated that the BOC signal is a rectangular square wave and can be represented as, for 10 example, ci(t)*sign(sin(2tfst)), where f, is the frequency of the subcarrier. One skilled in the art understands that BOC(fsfe) denotes Binary Offset Carrier modulation with a subcarrier frequency off, and a code rate (or chipping rate) offer. Using binary offset carriers results in the following signal descriptions of the signals emitted from the satellite: SL,(t) = Ascm(t)mr(t)d(t)cos(W2t) + Acscj (t)g(t)d,(t)sin(ct0) = Im 11 (t) +Qsy;(t), and 1 5 SL 2 (t = B,,,sc,,, (t)m, (t)dj (t) cos(o t) where Am, Ae and Bm are amplitudes; mi(t) is an m-code BOC(10,5) signal; g;(t) is a Galileo open service range code; 20 scim(t) represents the sub-carrier signal for m(t); scig(t) represents a subcarrier signal for ci(t); co1 and Co2 are the LI and L2 carrier frequencies; Figure 2 also illustrates power spectra for a BPSK-R1 code and pair of BOC signals, that is, BOC(2,1) and BOC(10,5). The first spectrum 202 corresponds to BPSK-R1 code. The second power spectrum 25 204 corresponds to the BOC(2,1) code and the third power spectrum 206 corresponds to the BOC(10,5) code. It can be appreciated that the side lobes 208 of the BOC(2,1) signal have relatively large magnitudes. Similarly, the illustrated side lobe 210 of the BOC(10,5) signal has a relatively large magnitude. One skilled in the art appreciates that the energy in the side lobes are a source of interference. 3 It is an object of embodiments of the present invention to at least mitigate the problems of the prior art. Summary of the Invention 5 According to a first aspect of the present invention there is provided a method of generating a subcarrier modulation signal for modulating ranging signal of a navigation system, the method comprising the steps of multiplexing in the time domain portions of first and second BOC signals to produce the subcarrier modulation signal. 10 According to another aspect of the present invention there is provided a method of generating a navigation signal comprising the steps of generating a subcarrier modulation signal as claimed in any preceding claim and modulating the ranging signal of the navigation system using said generated subcarrier modulation signal. 15 According to another aspect of the present invention there is provided an apparatus to generate a subcarrier modulation signal for modulating ranging signal of a navigation system, the system comprising means to multiplex in the time domain portions of first and second BOC signals to produce the subcarrier modulation signal. 20 According to another aspect of the present invention there is provided a system for generating a navigation signal comprising an apparatus to generate a subcarrier modulation signal as described above and means to modulate the ranging signal of the navigation system using said generated subcarrier modulation signal. 25 According to another aspect of the present invention there is provided a subcarrier modulation signal for modulating ranging signal of a navigation system, the subcarrier modulation signal comprising time domain multiplexed portions of first and second BOC signals to produce the subcarrier modulation signal. 30 According to another aspect of the present invention there is provided a navigation signal comprising a ranging signal modulated by a subcarrier modulation signal as described above. -4 N:\Melbourne\Cases\Patent\60000-60999\P60037 AU.1\Specis\P60037.AU.1 Specification Amendments 2009-3-19.doc 24/03/09 According to another aspect of the present invention there is provided a receiver comprising means to receive a navigation signal as described above. Brief Description of the Invention 5 Embodiments of the present invention will now be described, by way of example, only with reference to the accompanying drawings in which: Figure I shows a power spectrum of a pair of ranging code; 10 Figure 2 illustrates power spectra of a ranging code (BPSK-R 1) and BOC(l0,5) signals; Figure 3 illustrates a multi-level sub-carrier; 15 Figure 4 illustrates the phase states for at least a pair of multilevel subcarriers according to embodiments of the present invention; - 4a N:\Melbourne\Cases\Patent\60000-60999\P60037.AU 1\Specis\P60037.AU 1 Specification Amendments 2009-3-19.doc 24/03109 figure 5 depicts a power spectrum of a prior art subcarrier and a subcarrier according to embodiments of the present invention; figure 6 illustrates phase states for a subcarrier according to embodiments of the present invention; figure 7 illustrates in phase and quadrature phase subcarriers according to embodiments of the present invention; figure 8 illustrates phase states of a subcarrier according to an embodiment of the present invention; figure 9 shows subcarriers according to embodiments of the present invention; figure 10 depicts power spectra of subcarriers according to embodiments of the present invention; figure 11 illustrates subcarriers according to embodiments of the present invention; figure 12 shows an alternative subcarrier waveform according to an embodiment of the present invention; figure 13 illustrates a further. alternative waveform according to embodiments of the present invention; figure 14 illustrates, schematically, a transmitter using subcarriers according to embodiments of the present invention; and figure 15 illustrates a further embodiment 6f a transmitter according to an embodiment. Detailed Description of the Drawings Referring to figure 3, there is shown a first embodiment of a subcarrier 300. It can be appreciated that the sub-carrier is a 5-level approximation of a sinusoidal signal 302. It can be appreciated that the signal levels are (+1, +1/42, 0, -1/42, -1). Furthermore, it will be appreciated that the levels are the projections onto the x or I axis of a rotating vector at angles of r/4 radians having a unit magnitude. It will be further appreciated that, given the in-phase and quadrature-phase components of, for example, SL1i, that is, Asc,, (t)m(t)d,(t)cos(cot)=ISLwi(t) and Acscg(t)g,(t)d,(t)sin(cost)=Qsm 1 (t), the magnitude of the signal will be such that it is constant since the projection of the quadrature phase component onto the y or Q axis will also take the values (+1, +1/42, 0, -1/42, -1). It will be appreciated that there are preferably restrictions on the combinations of signals, at least one of which is that a constant modulus signal should be maintained. The constraints are (1) that "+1" or "-1" on the in-phase component can only occur in conjunction with "0" on the quadrature phase 5.
component and visa versa and (2) "±1/42" can only occur on both phases simultaneously. The magnitudes of the in-phase and quadrature phase components of the spreading signals, scig(t) or scjm(t), can be plotted on an Argand diagram 400 such as is shown in figure 4. The waveforms for the I and Q components are thus built from the following signal element sequences: I phase - (+1/42, +1, +1/42, 0) representing a +1 signal I phase - (-1/42, -1, -1/42, 0) representing a -1 signal Q phase - (+1/42, 0, -1/42, -1) representing a +1 signal Q phase - (-1/42, 0, +1/42, +1) representing a -1 signal. Any combination of I or Q signal sequences can be chosen from the above set within the constraint of a constant magnitude carrier signal, computed as (12+Q2)". It will be clear to those skilled in the art, that there are many other equivalent sets of sequences which may be chosen from the set of 5-levels satisfying the criterion of a constant carrier envelope. It can be appreciated that the magnitudes of the subcarriers on the I and Q channels can be thought of as being analogous to the states of an 8-PSK signal. Therefore, such a pair of 5-level subcarrier carrier signals can be thought of as 8 phase subcarrier signals. Figure 5 illustrates the effect of using a stepped or m-level, m>2, subcarrier waveform. Referring to figure 5 there is shown a pair 500 of power spectra. The first power spectrum 502, illustrated using the dotted line, represents the spectrum of a BOC(2,2) subcarrier. It can be appreciated that the energy of the subcarrier is contained within progressively reducing side lobes 504, 506, 508 and 510. The second power spectrum 512 represents the power spectrum of a BOC(2,2) signal that used 8 phase subcarrier signals, that is, 8 phase amplitudes, represented by BOC8(2,2). More generally, BOCm(f,,fe) represents an m-phase subcarrier signal ofhaving-a frequency off, and a chipping rate of f,. It can be appreciated that the spectrum 512 of the BOC8(2,2) signal has a number of side lobes 514, 516, 518, 520, 522 and 524. Of those side lobes, it can be seen that the 1st to 41 side lobes are 5 significantly reduced, that is, they comprise significant less energy, as compared to the side lobes of the BOC(2,2) signal spanning the same frequencies. The significant reduction in the 1 8t to 4h side lobes can be beneficial in situations in which one skilled in the art wishes to use the frequency spectrum spanned by the side lobes for other transmissions. It will be appreciated by those skilled in the art the BOC8(2,2) has significantly improved interference 0 properties as determined using Spectral Separation Coefficients (SSC) and self-SSCs as is well understood by those skilled in the art, that is, the spectral coupling between a reference signal and BOC(2,2) is greater than the spectral coupling between a reference signal and BOC8(2,2). For 6 example, a BOC8(2,2) signal exhibits a 10-12 dB improvement in spectral isolation as compared to a conventional BOC(2,2) signal. Further information on the relationship between SSC and signals according to embodiments of the present invention can be found in, for example, Pratt & Owen; BOC Modulation Waveforms, IoN Proceedings, GPS 2003 Conference, Portland, September 2003, which is 5 incorporated herein by reference for all purposes and filed herewith as in the appendix. Furthermore, embodiments of the present invention utilise the magnitude and duration of the subcarrier to influence, that is, control the energy in harmonics of the resulting modulating waveform. For example, referring still to figure 5, it can be appreciated that additional spectral nulls appear in the BOC8(2,2) spectrum at substantially 6MHz and 1OMT4z offset from the carrier whereas there are no t0 such nulls in the conventional BOC(2,2) signal. The location of the nulls is influenced by at least one of the magnitude and duration of the steps in the multilevel subcarrier. More specifically, the nulls can be steered to desired locations by changing either of these two elements, that is, the position of the nulls is influenced by these two elements. Appendix A contains an indication of the relationship between the spectra of signals according to embodiments of the present invention and the magnitude 5 and duration of the steps. Referring to figure 6, there is shown subcarrier states or amplitudes for I and Q signals for a further BOC8 signal, that is, a binary offset carrier having eight states. It can be appreciated that the eight states can be represented by, or correspond to, subcarrier amplitudes chosen from the set (--J/2,-1/2,+1/2,+ r3/2) ie four states or signal amplitudes rather than the five states or D signal amplitudes described above. Therefore, the I and Q components are constructed from the following signal elements such that V(cos 2 9 + sin 2 9) = 1, that is, ± I3 / 2 can only occur in conjunction with i 1/2, are as follows: I phase - (+1/2, +43/2, +43/2, +1/2) representing a +1 chip of a ranging code signal I phase - (-1/2, -43/2, -43/2, -1/2) representing a -1 chip of a ranging code signal 5 Q phase - (+43/2, +1/2, -1/2, 43/2) representing a +1 chip of a ranging code signal Q phase - (43/2, -1/2, +1/2, +43/2,) representing a -I chip of a ranging code signal. It will be appreciated that the states I to 8 shown in figure 6 are not equidistantly disposed circumferentially. The transitions between states 2&3, 4&5, 6&7, 8&1 are larger in angular step than the transitions between states 1&2, 3&4, 5&6, 7&8. It will be appreciated that when these states are 3 translated into subcarrier amplitudes, the duration of a given amplitude will depend on the duration or dwell time of a corresponding state, that is, the durations for which the subcarrier remains in any 7 given state may no longer be equal unlike the states of figure 4 above. The dwell times are a matter of design choice such as, for example, to minimise the mean square difference between a stepped waveform and a sinusoid. Figure 7a illustrates the subcarriers 700 and 702 corresponding to the states shown in figure 6. It can be appreciated that the durations of or within each state of the subcarriers 5 700 and 702 are equal. The Q channel subcarrier magnitudes will follow substantially the same pattern as described above but phase shifted by 7/2 radians. The subcarrier 702 for the Q channel is shown in dotted form in figure 7. It will be appreciated that such subcarriers provide a constant envelope magnitude since (I2+Q2)ln=I for all amplitude combinations. However, referring to figure 7b, there is shown a pair of subcarriers 704 and 706 in which the durations at each state are unequal. 10 It will be appreciated that not all amplitude combinations satisfy (12+QI)11=1. Therefore, the transmitted signal will not have a constant envelope. It will be appreciated by those skilled in the art that a stepped half cycle of the subcarrier corresponds to one chip. However, other embodiments can be realised in which other multiples of half cycles correspond to a chip. For example, embodiments can be realised in which two half cycles of a 5 subcarrier correspond to a chip. In such embodiments the signals for the I and Q channels would be I phase - (+1/2, +43/2, +43/2, +1/2, -1/2, -43/2, -43/2, -1/2) representing a +1 signal I phase - (-1/2, -43/2, -43/2, -1/2, +1/2, +43/2, +43/2, +1/2) representing a -1 signal Q phase - (+43/2, +1/2, -1/2, -43/2, -43/2, -1/2, +1/2, +43/2) representing a +1 signal Q phase - (-43/2, -1/2, +1/2, +43/2, +43/2, +1/2, -1/2, -43/2) representing a -l signal. 0 Similarly, embodiments realised using three half cycles per chip would produce I phase - (+1/2, +43/2, +43/2, +1/2, -1/2, -43/2, -43/2, -1/2, +1/2, +43/2, +43/2, +1/2) representing a +1 signal I phase - (-/2, 43/2, -43/2, -1/2, +1/2, +43/2, +43/2, +1/2, -1/2, -43/2, -43/2, -1/2) representing a -1 signal Q phase - (+43/2, +1/2, -1/2, -43/2, -43/2, -1/2, +1/2, +43/2, +43/2, +1/2, -1/2, -43/2) representing a +1 signal Q phase - (43/2, -1/2, +1/2, +43/2, +43/2, +1/2, -1/2, -43/2, -43/2, -1/2, +1/2, +43/2) representing a -1 signal. .5 One skilled in the art will appreciate that the above can be extended to n half cycles of a subcarrier per ranging code chip. It will be appreciated that other phases can be used to describe the subcarriers. For example, phase and amplitude components of 16-PSK can be used to create BOC16 subcarriers having 9 levels, assuming that the first state is at (+1,0). Using m-PSK phase states can be used to produce (m+2)/2 8 level subcarrier signals. Therefore, setting m=2 gives the conventional BPSK and a two-level subcarrier. Setting m=4 provides a 3 level subcarrier, that is, BOC4 modulation, setting m=8 produces a 5 level subcarrier, that is, BOC8 modulation, setting m=16 produces a 9 level subcarrier, which corresponds to BOC16 modulation. 5 It will be appreciated that several further variations in the assignment of code and data states to the phase locations can be realised. For example, rotation of the states shown in figure 4 by 22.5* leads to a reassignment of angles associated with the states from the angles (00, 450, 900, 135*, 180*, 2250, 2700, 3150) to the angles (22.50, 67.50, 112.50, 157.50, 202.50, 247.50, 292.5*, 337.50). Again, it will be appreciated that this does not cause a change in the modulus of the spectrum and, again, the 10 required number of amplitude levels reduces from 5 to 4, that is, m-PSK can be used to realise [(m+2)/2-1] amplitudes according to appropriate rotation and alignment of the phase states. The resulting waveforms for the I and Q components are built, in this case, from the following signal element sequences: I phase - (+cos(67.5*), +cos(22.5"), +cos(22.5*), +cos(67.5*)) representing a +1 signal [5 I phase - (-cos(67.5*), -cos(2 2
.
5 *), -cos(22.5*), -cos(67.5*)) representing a -l signal Q phase - (+sin(67.5 0 ), +sin(22.5"), -sin(22.5 0 ), -sin(67.5*)) representing a +1 signal Q phase - (-sin(67.
5 *), -sin(2 2 .5*), +sin(22.5*), +sin(67.S 0 )) representing a -1 signal. It should be noted that the I and Q signal element sequences for the cases described above are orthogonal over the duration of one spreading pulse (chip). Clearly, other rotations are possible and 0 will yield orthogonal signal element sets. An alternative way of representing the above is via a state table. Assume that an embodiment of a BOC8 modulation has been realised with equidistant states and the first state has a phase angle of n/8 radians (22.5*) as shown in figure 8, which corresponds to the above values. The sequence of phase states required for each I and Q ranging code signal component, assuming that the ranging codes 25 transition substantially simultaneously and a desire to maintain a substantially constant output envelope, that is, the states for the subcarriers would be given by 9 I Q t] t2 t3 t4 +1 +i 2 1 8 7 .1 +1 3 4 5 6 +1 -1 7 8 1 2 -1 -1 6 5 4 3 Table I - Sequence of States for BOC8(x,x) I & Q signal elements It will be appreciated that the subaarrier corresponding to the phase states in Table 1 comprises a half 5 cycle per ranging code chip. Furthermore, the sense of the phasor is clockwise when I and Q are equal and anticlockwise otherwise. It will be apparent that the signal element sequences or state sequences are sections (specifically half cycle sections in the aspect of the invention disclosed above) of a sampled or quantised sinusoid. The concept can, therefore, be extended to include a multiplicity of such samples. Those variants, which appear to be useful, include the cases with samples from a finite 10 number of half cycles, that is, rather than, for example, an I channel value of +1 being represented by the states of 2, 1, 8 and 7, it can be represented using some other number of states such as, for example, 2, 1, 8, 7, 6, 5, 4, 3, 2, 1, 8, 7 ie by three half cycles of the sample or quantised sinusoid. Table 2 illustrates the phase states for such an embodiment and is based on the phase state diagram of figure 4 for samples but using three half cycles (or an arbitrary number of half cycles) of the sinusoid 15 waveform. The sinusoid or portion or multiple of half cycles thereof is known as the 'basis waveform'. One skilled in the art realises that other basis waveforms can be used such as, for example, a triangular waveform or a set of mutually orthogonal waveforms. I Q tl t2 t3 t4 t5 t6 t7 t8 t9 t10 tll t12 +1 +1 2 1 8 7 6 5 4 3 2 1 8 7 -1 +1 3 4 5 6 7 8 1 2 3 4 5 6 +1 -1 7 8 1 2 3 4 5 6 7 8 1 2 - ..1 6 5 4 3 2 1 8 7 6 5 4 3 10 Table 2 - Sequence of States for 8-PSK I & Q Signal Elements with I 1/2cycles of sub-carrier per chip modulation I Q t1 t2 t3 t4 t5 t6 t7 t8 +1 1 2 1 8 7 6 5 4 3 -1 +1 3 4 5 6 7 8 1 2 +1 -1 7 8 1 2 3 4 5 6 1 -1 6 5 4 3 2 1 8 7 Table 3 - Sequence of States for 8-PSK I & Q Signal Elements with two half cycles of sub-carrier per 5 chip modulation. One skilled in the art will appreciated that it is assumed in Tables 1 to 3, that the I and Q chip transitions happen substantially simultaneously and, furthermore, that the I and Q subcarriers take the form of sine and cosine waveforms respectively. However, embodiments can be realised in which the ranging code chip transitions do not occur substantially simultaneously. Furthermore, in [0 circumstances in which the ranging code chip transitions do not occur substantially simultaneously, the subcarriers corresponding to the I and Q ranging code chips can be arranged to take the form of a pair of quantised sine waves. It will seen that there are 4 time samples for each K, cycle of the waveform. The stepped sinusoidal waveform may be viewed as sub-carrier modulation of the basic spreading waveform. The number of 15 time samples and independent information bearing channels is related to the number of phase states, which the carrier signal has in its representation. Although the examples above have used phase states that are 'powers of 2', embodiments can be realised in which some other number is used. For example, a 6-PSK carrier signal can be used to carry 2 independent information bearing binary channels. In this case only 3 signal element samples are required per transmitted code chip. 20 One skilled in the art appreciates that the replacement of the stepped sinusoid with a rectangular wave with the duration of each element being equal to a 2 cycle of the sinusoid is well known within the art. As indicated above, it is known as 'Binary Offset Carrier' modulation. There are usually 2 further attributes associated with the BOC description, which relate to the frequency of the code chipping rate 1 1 and to the frequency of the offset sub-carrier. BOC(2,2) consequently is interpreted as a waveform with a 2.046MHz chipping rate and a 2.046MHz offset sub-carrier. This arrangement has exactly two B cycles of the sub-carrier signal for each code element (chip). A further aspect of embodiments of the present invention relates to using a set of subcarriers to 5 modulate ranging codes, with at least one or more, or all, of the subcarriers being multilevel waveforms. One skilled in the art may think of such embodiments as modulation of the subcarrier signal by a further subcarrier signal. The resulting signal transmitted by an ith satellite or system having a carrier frequency of oi, for an additional subcarrier, would have the form: S,(t )= Amscm(I)sci,, (t)m, (t)d,(t)cos(cit) + Ac scjg(t)sci(t)g,(t)di(t)sin(ajit) = Isi () + Qs,(t ) 0 where sc,,(t) and scjm(t) represent first and second subcarrier signals respectively first ranging codes such as, for example, M-codes; and scig(t) and scjg(t) represent first and second subcarrier signal second ranging codes such as, for example, Gold codes. 5 It should be noted that embodiments can be realised in which scim(t) and scig(t) are the same or different. Similarly, embodiments can be realised in which scjm(t) and scig(t) are the same or different. S,(t) = A, lscm(t )m,it)d,(t)cos(Wit)+ Ac H7scg(g)g(t)dj(t)sin(cit ) = Isi(t) + Qs, (t), j=1 j=I n where H sc,,,,,(t) and 7 sc, (t) represents the product of the subcarriers for the first and second 1=1 j=1 ranging codes such as, for example, the m and Gold codes. 0 Although it is possible to use more than one subcarrier, practical embodiments will typically use 2 subcarriers. Modulation using a pair of subcarriers is known as Double Binary Offset Carrier (DBOC) modulation. Modulation using three subcarriers is known as Triple Binary Offset Carrier (TBOC) modulation and so on such that modulation using a n-tuple of subcarriers is known as N-tuple Binary Offset Carrier (NBOC). As mentioned above, one or more than one of the subcarriers may be 5 stepped, that is, having magnitudes related to respective phase states. As examples of this aspect of the invention, figure 9 illustrates a pair of waveforms 900. In figure 9, as an illustration of the NBOC invention, the subcarrier basis waveforms are assumed to be binary and only a single subcarrier waveform 902 is shown. The time duration in figure 9 is 512 samples and 12 exactly matches the duration of one code element duration (chip). The first subcarrier 902 contains 4 half cycles of a subcarrier per ranging code chip, as illustrated by the dashed waveform. If this was the only sub-carrier component, the modulation would be a BOC(2xx) type, where x is the frequency of the code rate (chipping rate). However, it can be appreciated that a second sub-carrier (not shown) 5 having 16 half cycles per 512 samples has been used to produce the modulated waveform 904 to be combined with the carrier of the satellite signal. The modulated waveform is shown by the solid curve. As a result of modulation (multiplication) of the two subcarriers, the resulting waveform 904 has phase reversals for the second subcarrier 904 whenever there is a sign reversal in the first subcarrier 902. This is clearly evident in figure 9 at points 906, 908 and 910, where the transitions of 0 the second subcarrier (not shown) would have been opposite. The resulting modulation is denoted Double BOC, or DBOC. In the case of figure 9, the modulation is DBOC(8x,(2x,x)), that is, there are 8 half cycles of the second subcarrier per chip of the ranging code (not shown). The main energy is concentrated around frequencies ±8x from the carrier signal, with a BOC-like double humped spectrum. 5 Referring to figure 10, there is shown a pair of power spectra 1000. A first power spectrum 1002 related to a DBOC8(16,(2,2)) signal. It will be appreciated that at least one of the first and second subca.riers used to create the DBOC8(16,(2,2)) signal comprised amplitudes derived from 8 corresponding phase states. In the specific embodiment shown, the first subcarrier was the multi-level signal It will be appreciated that the nomenclature for representing DBOC modulation or subcarriers J is DBOCa(b,c(d,e)), where a and c represent the number of phase states, that is, amplitudes, of the subcarriers having frequencies b and d respectively. The second spectrum 1004 relates to a BOC8(2,2) signal. The spectra shown have been made using a previous aspect of the invention, that is the use of multilevel subcarriers or subcarriers having more than two phase states, in combination with the Double BOC concept. The waveforms for I & Q modulations for the spectrum of figure 10 are shown in figure 11. Referring to figure 11 there is shown a pair 1100 of waveforms. The first pair of waveforms 1102, representing the I channel of the spreading waveform, comprises a stepped or multi level BOC(2,2) signal 1104, represented by the solid line, and a 16Mhz subcarrier modulated BOC(2,2) signal 1106, represented by the dashed line. It will be appreciated that the 16 MHz subcarrier modulated BOC(2,2) signal has been produced by multiplying the BOC8(2,2), that is, 0 stepped BOC(2,2) signal, by a 16 MHz rectangular waveform (not shown) having amplitudes of +1. The second waveform 1108, representing the Q channel, comprises a quadrature BOC(2,2) signal 1110 together with a 16MiHz subcarrier modulated BOC(2,2) signal 1112. It can be appreciated that the first subcarrier 1104 or 1110 is a subcarrier according to an embodiment of the present invention described above whereas the second sub-carrier (not shown) in both cases are conventional binary 5 rectangular waveforms, that is, conventional subcarriers. It can be appreciated that there are regions 1114 of overlap between the two BOC(2,2) subcarriers 1104 and I110 and their resulting products, 13 that is, 16 MHz subcarrier modulated BOC(2,2) signals 1106 and 1112. In the regions of overlap 1114, the waveforms have the same amplitude profile. An advantage of the embodiments of the signals shown in figure I I is that the I channel or component has been produced or represents DBOCS modulation or signal whereas the Q channel has been 5 produced using or represents BOC8 modulation. However, this arrangement still preserves or provides a substantially constant envelope carrier signal to be emitted from the satellite. Embodiments of the present invention have been described with reference to the subcarrier signals being periodic. However, embodiments can be realised in which the subcarrier signal comprises a pseudorandom noise signal. Furthermore, embodiments can be realised in which the shape of the 10 subcarrier takes a form other than a stepped, that is, a multilevel wave or quantised approximation of a sinusoidal waveform. For example, multilevel-pulsed waveforms, multilevel-periodic waveforms or multilevel-aperiodic waveforms, could be used such as the signal shown in figure 12 according to the influence one skilled in the art wishes the resulting modulation to have on the power spectrum of the transmitted signal and/or any appropriate measure of interference such as, for example, SSC or self 15 SSCs. Referring to figure 13, there is shown a subcarrier waveform 1300 according to a further embodiment of the present invention together with one chip 1302 of a code or other waveform such as, for example, another subcarrier. It can be appreciated that the subcarrier comprises a first portion of a BOC(5,1) waveform, in the 100 ns sections, combined with portions of a BOC(1,l) waveform, in the 20 400 ns portions, to produce an overall subcarrier. It will be appreciated that the spectra of the BOC(5,1) waveform will have a peak at 5*1.023MHz and the BOC(l,1) waveform will have a peak at 1*1.023MHz. Therefore, one skilled in the art appreciates that selectively combining the BOC subcarriers allows one skilled in the art to position or relocate the peaks of the overall subcarrier. Again, it can be appreciated that the subcarrier used, for example, to modulate the ranging codes is 25 derived from more than one subcarrier. Although the signal described in relation to figure 13 has been derived from BOC(5,1) and BOC(l,l) subcarriers, embodiments can be realised in which other combinations of BOC subcarriers are used. In effect, the BOC(5,1) and BOC(1,1) signals have been multiplexed or selectively combined to produce an overall subcarrier signal. It will be appreciated that other sequences for the subcarriers can be realised according to a desired effect upon the power 30 spectrum of a transmitted signal. For example, a subcarrier can be realised using a pseudorandom sequence as a sub-carrier instead of the stepped modulations. The use of additional sequences to that of the main spreading code has hitherto been Iiniited to use as a tiered code, which changes state after every complete code repetition interval. The GPS LS codes are constructed in this manner using Neumann Hoffman sequences of length 10 or 20 to extend a ims code (of 10230 chips or elements) to 35 lOms or 20ms. The use of a subcode chip interval has not previously been considered. A complete 14 sequence (a sub-sequence) has a duration of one code chip, or at most a plurality, of code chips. It fulfills a similar role to the sub-carrier modulation as previously described in that it controls the spectrum of the emissions. One feature of such a sub-sequence is that such sequences may be chosen to be common amongst a satellite constellation or a sub-set of the constellation. One such subset 5 might be a group of ground transmitters providing a local element or augmentation to the space segment of the system. For example, subcarrier amplitudes can be realised that have the sequence ++++---+ in 10 subchip intervals or other sequence of +1's and -l's per ranging code chip or other subcarrier chip according to the desired effect on spectrum of the resulting signal. Examples such as the 7 subchip interval sequences would include ++--, -+-, -- +-, and can be chosen to provide 10 similar control over the emitted spectrum. Referring to figure 14, there is shown, schematically, a transmitter 1400 according to an embodiment of the present invention. The transmitter 1400 comprises means 1402, that is, a generator, for generating or selecting the ranging codes for transmission. It will be appreciated by those skilled in the art that such ranging codes may be generated by, for example, shift register implementations. It 15 can be appreciated that the ranging code selection and/or generation means 1402 is illustrated as producing g,(t) and m,(t). These codes are fed to respective mixers 1404 and 1406. The mixers 1404 and 1406 are arranged to combine the ranging codes with subcarriers according to embodiments of the present invention. Respective subcarrier generators 1408 and 1410 generate the subcarriers. Optionally, a data signal, d,(t), is also preferably mixed with the ranging codes and subcarriers. The 20 duration of one bit of the data signal is normally an integer multiple of the code repetition interval. For example, in GPS CA code, it is 20 times the 1 ms code repetition interval, that is, the data rate is 50 bps. The mixed signals 1412 and 1414 are fed to a further pair of mixers 1416 and 1418, where they are mixed with in-phase and quadrature phase signals produced via an oscillator and phase shifter assembly 1420. The further mixed signals 1422 and 1424 are combined, via a combiner 1426, and 25 output for subsequent up conversion by an appropriate up converter 1428. The output from the up converter 1428 is fed to a high-power amplifier 1430 and then filtered by an appropriate filter 1433 for subsequent transmission by, for example, a satellite or other device arranged to emit or transmit the ranging codes. Referring to figure 15, there is shown a schematic representation of a modulation system 1500 30 according to an embodiment. The system 1500 comprises a ranging code generator 1502 for producing a ranging code. The ranging code is fed to a first lookup table 1504 comprising phase states and a second lookup table 1506 comprising amplitude states. The output of the phase state lookup table 1504 is used to drive a phase modulator 1508, which, in turn, produces a voltage signal to control the phase of a voltage controlled oscillator 1510. The output of the oscillator 1510 is 35 combined, via, a combiner 1512 such as, for example, a gain controlled amplifier or multiplier, with a 15 signal output from the amplitude state table 1506 to produce a subcarrier having the appropriate characteristics. Although the above embodiments have been described with reference to maintaining a substantially constant signal envelope, embodiments are not limited thereto. Embodiments can be realised in which variable modulus signal envelopes are used. It will be appreciated that the constraints described above, which are aimed at preserving unitary magnitude of (1+Q 2 1/, need not necessary apply. The above embodiments have been described with reference to the I and Q channels having the same chipping rates. However, embodiments are not limited to such arrangements. Embodiments can be realised in which different chipping rates are used. Although embodiments of the present invention have been described with reference to the Li and L2 frequencies, embodiments are not limited to such arrangements. Embodiments can be realised in which other frequencies or frequency bands can be used according to the requirements of the system using the invention. For example, the lower L band (ie E5a and E5b), the middle (ie E6) and upper L band (ie E2-L1-El) can also benefit from embodiments of the present invention. It will be appreciated that such embodiments may use signals having at least three components rather than the two components described above. Furthermore, embodiments of the present invention have been described with reference to standard BOC. However, one skilled in the art appreciated that embodiments can also be realised using Alternative BOC. Furthermore, it will be appreciated that embodiments can be realised in which the number of half cycles of a subcarrier per chip of a code can be at least one of odd, even, an integer multiple or a non integer multiple of the chip, that is, there is a rational number relationship between the number of subcarrier half cycles and the chip duration. 5 Embodiments of the present invention described above have focused on the transmission side of the invention, that is, upon the generation, modulation and transmission of ranging codes combined with a subcarrier or subcarriers. However, one skilled in the art appreciated that a converse system and method are required to receive and process the signals. Once one skilled in the art has designed a system for transmitting such signals, designing an appropriate receiver is merely the converse of the 0 transmit operations. Therefore, embodiments of the present invention also relate to a receiver for processing signals such as those described above. 16 The reader's attention is directed to all papers and. documents that are filed concurrently with or previous to this specification in connection with this application and which are open to public inspection with this specification, and the contents of all such papers and documents are incorporated S herein by reference. All of the features disclosed in this specification (including any accompanying claims, abstract and drawings), and/or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least sorne of such features and/or steps are mutually 10 exclusive. Each feature disclosed in this specification (including any accompanying claims, abstract and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example only of a generic series of equivalent or similar features. The invention is not restricted to the details of any foregoing embodiments. The invention extends to 15 any novel one, or any novel combination, of the features disclosed in this specification (including any accompanying claims, abstract and drawings), or to any novel one, or any novel combination, of the steps of any method or process so disclosed. In the claims which follow and in the preceding description, except where the context requires 20 otherwise due to express language or necessary implication, the word "comprise" or variations such as "comprises" or "comprising" is used in an inclusive sense, i.e. to specify the presence of the stated features but not to preclude the presence or addition of further features in various embodiments of the invention. It is to be understood that, if any prior art publication is referred to herein, such reference does 25 not constitute an admission that the publication forms a part of the common general knowledge in the art, in Australia or any other country. 17 N \Mclboume\Cases\Patent\60000-60999\P60037 AU I \Specis\P60037 AU I Specification 2007-8.3 doc 7/08/07

Claims (11)

  1. 2. A method as claimed in claim I wherein said multiplexing in the time domain comprises multiplexing in the time domain a portion of a BOC(5,1) subcarrier signal, 10 spanning 100 ns, and a portion of a BOC(l,1) subcarrier signal spanning a 400 ns time interval.
  2. 3. A method of generating a navigation signal comprising the steps of generating a subcarrier modulation signal as claimed in any one of the preceding claims and is modulating the ranging signal of the navigation system using said generated subcarrier modulation signal.
  3. 4. Apparatus to generate a subcarrier modulation signal for modulating ranging signal of a navigation system, the system comprising 20 means to multiplex in the time domain portions of first and second binary offset carrier (BOC) signals to produce the subcarrier modulation signal.
  4. 5. Apparatus as claimed in claim 4 wherein said means to multiplex in the time domain comprises means to multiplex in the time domain a portion of a BOC(5,I) 25 subcarrier signal, spanning 100 ns, and a portion of a BOC(1,1) subcarrier signal spanning a 400 ns time interval.
  5. 6. A system for generating a navigation signal comprising an apparatus to generate a subcarrier modulation signal as claimed in any one of claims 4 to 5 and means to 30 modulate the ranging signal of the navigation system using said generated subcarrier modulation signal.
  6. 7. A subcarrier modulation signal for modulating ranging signal of a navigation system, the subcarrier modulation signal comprising time domain multiplexed portions 35 of first and second binary offset carrier (BOC) signals to produce the subcarrier modulation signal. - 18 N:\Velbourne\Cases\Patent\60000-60999\P60037.AU.1\Specis\P60037.AU.1 Specification Amendments 2009-3-19 doc 24/03/09
  7. 8. A subcarrier modulation signal as claimed in claim 7 wherein said time domain multiplexed portions of the first and second BOC signals time domain multiplexed portions a portion of a BOC(5,1) subcarrier signal, spanning 100 ns, and a portion of a BOC(I, 1) subcarrier signal spanning a 400 ns time interval. 5
  8. 9. A navigation signal comprising a ranging signal modulated by a subcarrier modulation signal as claimed in either of claims 7 and 8.
  9. 10. A receiver comprising means to receive a navigation signal as claimed in claim 10 9. I1. A method as claimed in any one of claims 1 to 3, and substantially as herein described with reference to the accompanying drawings. is 12. An apparatus as claimed in any one of claims 4 to 6, and substantially as herein described with reference to the accompanying drawings.
  10. 13. A signal as claimed in any one of claims 7 to 9, and substantially as herein described with reference to the accompanying drawings. 20
  11. 14. A receiver as claimed in claim 10, and substantially as herein described with reference to the accompanying drawings. - 19 N:\Melbourne\Cases\Patent\6OOOO-60999\P60037.AU. 1\Specis\P60037 AU.1 Specification Amendments 2009-3-19.doc 24/03/09
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