The present application relates to an oscillator making it possible to generate an adjustable-frequency electric signal.
The field of the invention is the field of electronic circuits and, in particular, of integrated electronic circuits used in the radiofrequency and microwave frequency fields, for example in communication systems.
In the radiofrequency and microwave frequency fields, the most used method for obtaining an adjustable-frequency oscillator consists of modifying the phase-frequency characteristic of the resonator.
In particular, oscillators can be mentioned which are designed around one or more varactors (or voltage-controlled variable capacitors).
This type of component does not however generally allow a frequency variation greater than one octave. Moreover, if it is desired to fully integrate the oscillator, the technology used during the design of the integrated circuit most often complies with choices which are not optimized, in order to obtain a maximum variation of the value of the capacitance of the varactor. The variable capacitor does not therefore make it possible to obtain a frequency variation over a wide frequency band or it must be located outside of the integrated circuit.
Moreover, the introduction of variable components in the resonator creates losses, which reduces the quality factor of the loaded resonator.
A purpose of the present invention is to overcome the above-mentioned drawbacks.
Another purpose of the invention is to propose an oscillator making it possible to obtain a frequency variation range which is wider than that of currently existing oscillators.
Another purpose of the invention is to propose an oscillator which makes it possible to obtain a variable-frequency signal and which improves the noise characteristic.
Finally, another purpose of the invention is to propose an oscillator which can be fully integrated.
In order to achieve at least one of these objectives, the invention proposes an oscillator for generating an adjustable-frequency signal, said oscillator comprising a looped system, called principal, said principal looped system comprising:
In order for oscillations to be established in the oscillator, one of the criteria defined by theory entails the existence in the looped system of a phase shift which is a whole multiple of 2π. As the phase shift device imposes an adjustable phase shift in the looped system, the resonator therefore introduces a complementary phase shift such that the sum of these two phase shifts is a whole multiple of 2π. The complementary phase shift introduced by the resonator therefore defines the oscillation frequency, by the intermediary of the phase-frequency characteristic of that resonator.
Thus, the invention proposes an oscillator providing a signal the frequency of which is adjusted by a phase shift. The oscillator according to the invention therefore makes it possible to carry out an adjustment/variation of the frequency without modifying the phase-frequency characteristic of the resonator used, in particular without modifying the value of a component element of the oscillator, such as for example a capacitive element and or an inductive element.
The frequency of the signal provided/generated by the oscillator according to the invention is directly adjusted by the phase shift applied by the phase shift device.
The oscillator according to the invention can be capable of complete integration.
Moreover, the oscillator does not comprise any capacitive element the value of which can be modified.
Moreover, the range of variation of the frequency is directly dependent on the range of variation of the phase shift value. For example, a range of variation of the phase shift value of 180° or of 360° makes it possible to obtain, with the oscillator according to the invention, a range of variation of the frequency greater than that obtained with presently existing oscillators.
The use of a phase shift device combined with a resonator makes it possible to obtain a variable-frequency signal with less noise.
Advantageously, the principal phase shift device can comprise several phase shift stages, connected in series, each phase shift stage defining a level of phase shift.
The use of several phase shift stages makes it possible, by making use of phase shift stages having a small phase shift range or small phase shift ranges, to obtain a large “overall” phase shift range for the principal phase shift device and thus to have a large range of variation of the frequency of the output signal of the oscillator.
The use of several phase shift stages also makes it possible to obtain several independent means for adjusting the phase shift.
In the present application, the verb “connect” denotes a direct or indirect connection between two elements.
Advantageously, the at least one means of adjusting the phase shift produced by said phase shift device can comprise:
According to a particularly advantageous embodiment that is in no way limitative, the at least one phase shift means can be reduced to a line entering one or more phase shift stages and provided for conveying a phase shift control signal, generated by a means outside of the oscillator, this control signal causing the phase shift in the phase shift stage or stages to vary. In this case, the control signal can be a control voltage.
According to a particular embodiment, at least one phase shift stage can comprise:
Such a phase shift stage makes it possible to phase-shift the principal signal by an adjustable phase shift value.
Thus, in this particularly advantageous embodiment of the oscillator according to the invention, the phase shift of a signal is produced by analogue multiplication of this signal by control voltages, according to the following trigonometric equations:
cos(ωt)*cos(a)+sin(ωt)*(−sin(a))=cos(ωt+a), when the signal the frequency of which is adjusted is a cosine and
sin(ωt)*cos(a)+cos(ωt)*sin(a)=sin(ωt+a), when the signal the frequency of which is adjusted is a sine
where ω is the angular frequency of the signal generated.
In this embodiment, the control voltages can be:
In this embodiment, the control voltages directly modify the phase of the signal within the looped system.
When the principal looped system comprises several phase shift stages, as each of the phase shift stages defines a level of phase shift, each phase shift stage receives as input a principal signal and a secondary signal and provides the phase-shifted principal signal. This phase-shifted principal signal becomes the principal signal for the following stage.
In a particular embodiment, the secondary signal can be obtained from the incoming principal signal of each phase shift stage. In order to do this, the oscillator according to the invention comprises, upstream of each principal phase shift stage of a given level, a constant phase-shifter, the phase-frequency characteristic of which exhibits a phase shift which is constant with respect to frequency and generating the secondary signal for said principal phase shift stage from the principal signal.
When the principal signal is a cosine, the constant phase-shifter provides a sine of the same amplitude and of the same frequency as the principal signal. In the case where the principal signal is a sine, the constant phase-shifter provides a cosine of the same amplitude and of the same frequency as the principal signal.
In another embodiment, the secondary signal can be obtained from a second looped system, called secondary. Thus, the oscillator according to the invention can comprise a second looped system, called secondary, said secondary looped system comprising:
The function of the secondary looped system is to provide the secondary signal to each phase shift stage. In order to do this, the secondary looped system comprises as many phase shift stages as there are in the principal looped system, i.e. as many phase shift levels as there are in the principal looped system. Each secondary phase shift stage produces a phase shift of the same value as the phase shift produced by a principal phase shift stage of the same level and provides the secondary signal to the principal phase shift stage of the following level. The secondary signal used by the principal phase shift stage of the first level of phase shift is obtained at the output of the resonator of the secondary looped system.
In a particular embodiment of the secondary looped system:
Thus, each secondary phase shift stage uses the principal signal in order to obtain the secondary signal by analogue multiplication with control voltages. The control voltages used by the principal and secondary phase shift stages of the same level produce a phase shift of the same value. The secondary signal is obtained according to the following trigonometric equations carried out by each of the secondary phase shift stages:
cos(ωt)*cos(a)+sin(ωt)*(−sin(a))=cos(ωt+a), when the signal the frequency of which is adjusted, i.e. the principal signal, is a sine and
sin(ωt)*cos(a)+cos(ωt)*sin(a)=sin(ωt+a), when the signal the frequency of which is adjusted, i.e. the principal signal, is a cosine.
where ω is the angular frequency.
In this embodiment, the output of each resonator (principal and secondary) is connected to an input of each first level phase shift stage (principal and secondary) and the output of each phase shift stage (principal and secondary) of a given level of phase shift is connected to an input of each phase shift stage (principal and secondary) of the level following.
According to an embodiment of a phase shift stage, at least one multiplier of a phase shift stage can comprise:
Moreover, two multipliers of two phase shift stages of the same level of phase shift and receiving the same signals can comprise:
Moreover, two multipliers of two phase shift stages of a same level of phase shift and receiving different signals can comprise:
The fact of placing an amplification circuit or a switching circuit in common for two multipliers makes it possible to reduce the number of components and therefore to reduce the manufacturing cost and the dimensions of the oscillator.
The oscillator according to the invention can also comprise a power divider, arranged upstream of each phase shift stage.
The oscillator according to the invention can also comprise at least one amplifier arranged in each looped system, more particularly at the input of each phase shift device.
In a particular embodiment, at least one resonator can be a transmission line, the phase-frequency characteristic of which is linear or non-linear.
Advantageously, the oscillator according to the invention can be produced using integrated circuit technology.
The oscillator according to the invention is particularly suitable for use in the radiofrequency or microwave frequency field or in the optical field in order to obtain an adjustable-frequency signal.
Other advantages and characteristics of the invention will become apparent on examination of the detailed description of an embodiment which is in no way limitative, and the attached diagrams, in which:
The oscillator 100 shown in
The oscillator 100 comprises moreover means for adjusting the phase shift produced by the phase shifter 104. In the example shown in
The resonator 106 can be, but is not limited to, a transmission line the phase-frequency characteristic of which is linear.
The oscillator 200 is a looped system comprising a phase shift device 202 comprising a plurality of adjustable phase shifters 1041-104n connected in series, a resonator 106 arranged downstream of the phase shift device 202 and an amplifier 108 arranged upstream of the phase shift device 202. The output of the resonator 106 is connected directly to the input of the amplifier 108.
The oscillator 200 comprises moreover means for adjusting the phase shift produced by each phase shifter 104. In the example shown in
Each phase shifter 1041-104n defines a level of phase shift. Thus, the phase shifter 1041 corresponds to the first level of phase shift, the phase shifter 104n corresponds to the phase shift of level n. The looped system of the oscillator 200 therefore comprises n levels of phase shift, where n is a positive integer.
The oscillator 300 comprises a looped system 302.
The looped system 302 comprises a phase shift device 304 comprising a phase shift stage 306, an amplifier 108 arranged upstream of the phase shift device 304 and a resonator 106 arranged downstream of the phase shift device 304.
The phase shift stage 306 comprises a first multiplier 308 providing a first signal corresponding to the product of the signal to be phase-shifted, hereinafter called the “principal signal” and a first control voltage. The phase-shift stage 306 comprises a second multiplier 310 providing a second signal, corresponding to the product of a signal, called the secondary signal, and:
The phase shift stage 306 comprises moreover an adder 312 arranged downstream of the multipliers 308 and 310 and adding the signals provided by the multipliers 308 and 310.
The first control voltage is provided to the phase shift stage 306 and more particularly to the multiplier 308 by a control line represented by the arrow 314.
The second or the third control voltage is provided to the phase shift stage 306 and more particularly to the multiplier 310 by a control line represented by the arrow 316.
The oscillator 300 also comprises a constant phase shifter, the phase-frequency characteristic of which exhibits a phase shift which is constant with respect to frequency, 318, arranged between the amplifier 108 and the phase shift stage 306 and providing the secondary signal from the principal signal. The phase shifter 318 is provided for:
The sum of the signals thus obtained at the output of the adder 312 corresponds to the principal signal shifted by the phase shift value according to the following equations:
cos(ωt)*cos(a)+sin(ωt)*(−sin(a))=cos(ωt+a), when the principal signal is a cosine and
sin(ωt)*cos(a)+cos(ωt)*sin(a)=sin(ωt+a), when the principal signal is a sine
“a” being the adjustable phase shift value and ω being the angular frequency of the generated signal.
The oscillator 400 comprises a looped system 402.
The looped system 402 comprises a phase shift device 404 comprising a plurality of phase shift stages 3061-306m connected in series and each defining a level of phase shift, an amplifier 108 dispose upstream of the phase shift device 404 and a resonator 106 arranged downstream of the phase shift device 404.
Each phase shift stage 3061-306m of the phase shift device 404 is identical to the phase shift stage 306 of
According to the chosen configuration, the control voltages can be adjusted independently for each phase shift stage 3061-306m or in a way which is common to all or a portion of the phase shift stages 3061-306m.
The oscillator 400 also comprises a constant phase shifter, 3181-318m for each phase shift stage 3061-306m, arranged upstream of each phase shift stage 3061-306m and providing the secondary signal to the phase shift stage 306 of a given phase shift level from the principal signal received from the phase shift stage of the preceding level of phase shift. Each constant phase shifter 3181-318m is identical to the constant phase shifter 318 in
The oscillator 500 in
The principal looped system 502 comprises an amplifier 108, a resonator 106 and a principal phase shift device 506 comprising a phase shift stage 306 identical to the phase shift stage 306 shown in
The function of the secondary looped system 504 is to provide the secondary signal used by the principal phase shift stage 306 of the principal looped system 502. In order to do this, the secondary looped system 504 comprises a phase shift device 510, called secondary, comprising a phase shift stage 512, called secondary, supplying the secondary signal by analogue multiplication with control voltages, an amplifier 514 arranged upstream of the secondary phase shift stage 512 and a resonator 516 arranged downstream of the secondary phase shift stage 512. The output of the resonator 516 is connected to the input of the amplifier 514.
A power divider 518 is arranged between the amplifier 514 and the secondary phase shift stage 512.
The secondary phase shift stage 512 is identical to the principal phase shift stage 306 and comprises:
The first control voltage is provided to the secondary phase shift stage 512 by a control line represented by the arrow 526. The second or the third control voltage is provided to the secondary phase shift stage 512 by a control line represented by the arrow 528.
The first, second and third control voltages used by the principal phase shift stage 306 and the secondary phase shift stage 512 are identical. Thus, the phase shift stages 306 and 512 apply the same phase shift to the principal signal and to the secondary signal respectively.
The sum of the signals thus obtained at the output of the adder 524 corresponds to the secondary signal shifted by the phase shift value applied to the principal signal by the principal phase shift stage 306:
cos(ωt)*cos(a)+sin(ωt)*(−sin(a))=cos(ωt+a), when the principal signal is a sine and
sin(ωt)*cos(a)+cos(ωt)*sin(a)=sin(ωt+a), when the principal signal is a cosine.
where “a” is the phase shift value and ω is the angular frequency of the generated signal.
The principal signal and the secondary signal are each divided into two by the power dividers 508 and 518 respectively and provided to each of the principal 306 and secondary 512 phase shift stages.
The principal and secondary looped systems provide two signals in quadrature.
The oscillator 600 shown in
The oscillator 600 also comprises a secondary looped system 606 comprising an amplifier 514, a resonator 516 and a secondary phase shift device 608 comprising as many secondary phase shift stages 5121-512p, connected in series and identical to the secondary phase shift stage 512 in
Before each principal phase shift stage 3061-306p is arranged a power divider 5081-508p, dividing the principal signal coming from the preceding level of phase shift in order to inject it into the principal phase shift stage and the secondary phase shift stage of the following level.
Before each secondary phase shift stage 5121-512p, is arranged a power divider 5181-518p, dividing the secondary signal coming from the preceding level of phase shift in order to inject it into the principal phase shift stage and the secondary phase shift stage of the following level.
The phase shift stage 700 comprises, for each multiplier of the phase shift stage, a switching circuit 702 and 704, each comprising four transistors connected two by two as differential pairs and controlled by the control voltages. Each multiplier also comprises an amplifier circuit 706 and 708 comprising two transistors connected as a differential pair and coupled with the switching circuits, 702 and 704 respectively. The resistors 710 and 712 inserted between the power supply line Vcc and the collectors of the transistors carry out the operation of summing the signals and more particularly the addition of the currents.
When two multipliers of two phase shift stages of the same level use the same signals, a more compact architecture can be proposed for producing these two multipliers.
Thus,
Each of the two multipliers of two phase shift stages of the same level receiving the same signals comprise a switching circuit 802 and 804, each switching circuit 802 and 804 comprising four transistors connected two by two as differential pairs and controlled by the control voltages. According to the architecture proposed in
In the architecture shown in
Thus, two transmission lines 812 and 814 each constitute a connection with the phase shift stages of the level of phase shift following or the resonator and convey either the principal signal or the secondary signal.
Two other transmission lines 816 and 818 each convey the signal obtained at the output of a multiplier and which is to be summed with the signal obtained at the output of the other multiplier of the same phase shift stage.
When two multipliers of two phase shift stages of the same level use different signals, a more compact architecture can also be proposed for producing these two multipliers.
Thus,
Each of the two multipliers of two phase shift stages of the same level receiving different signals comprise an amplification circuit 902 and 904, each amplification circuit 902 and 904 comprising four transistors connected two by two as differential pairs, the bases of which are connected to a resonator or to the outputs of the phase shift stages of the preceding level of phase shift. According to the architecture proposed in
The resistors 908 and 910 inserted between the power supply line Vcc and the collectors of the transistors carry out the operation of summing the signals and more particularly the addition of the currents.
In the architecture shown in
Thus, two transmission lines 912 and 914 each constitute a connection with the phase shift stages of the following level of phase shift or with the resonator and convey either the principal signal or the secondary signal.
Two other transmission lines 916 and 918 each convey the signal obtained at the output of a multiplier and which is to be summed with the signal obtained at the output of the other multiplier of the same phase shift stage.
The oscillator 1000 shown in
The resistors 808 and 810 of a phase shift stage are replaced by inductances. Thus, the oscillator 1000 comprises two inductances 1002 and 1004 for the principal shift stage and 1002′ and 1004′ for the secondary phase shift stage.
The oscillator 1000 comprises moreover two switching circuits per phase shift stage, namely the switching circuits 802 and 804 for the principal phase shift stage and the switching circuits 802′ and 804′ for the secondary phase shift stage.
Each phase shift stage comprises an amplifier circuit, namely the amplifier circuit 806 for the principal phase shift stage and the amplifier circuit 806′ for the secondary phase shift stage. The resistor of each amplifier circuit is also replaced by an inductance.
Resonators 1006 and 1008, which are transmission lines, make it possible to loop back the signal coming from the principal phase shift stage to the input of the principal phase shift stage.
Similarly, resonators 1006′ and 1008′, which are transmission lines, make it possible to loop back the signal coming from the secondary phase shift stage to the input of the secondary phase shift stage.
In the examples described, it is also possible to replace at least one of the resistors 710, 712, 908 and 910, by an impedance, having a non-zero imaginary part. These impedances can correspond at least partly to all or part of the resonator.
Of course, the invention is not limited to the examples which have just been described and numerous adjustments can be made to these examples without exceeding the scope of the invention.
Number | Date | Country | Kind |
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10 57709 | Sep 2010 | FR | national |
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20120249248 A1 | Oct 2012 | US |