The present invention relates to power sensors, in particular sensors for measuring absolute power of microwave signals in cryostats.
Many devices that operate at low temperature, such as quantum devices and superconducting qubits, use or process microwave signals, that is signals with frequencies in the range of from 1 to 50 GHz. Such signals are transmitted over transmission lines. Progress in development of microwave superconducting circuitry, in particular for application to quantum computing and quantum optics, demands calibration of microwave lines and knowledge of applied powers to the circuits situated at low temperatures. To date, there is no method for measuring the absolute power of a microwave signal in a continuous transmission line at low temperatures, e.g. less than 5 K. US 2009/0289638 discloses an arrangement for measuring the state of a qubit by measuring the power of a standing wave in a transmission line cavity that supports a single mode. Known power meters and spectral analysers rely on semiconductor-based electronics that do not function at low temperatures.
Therefore, it is necessary to bring a microwave signal to be measured out of the cryostat so that its power can be measured at room temperature. However, the power measured at room temperature cannot accurately indicate the power at the point of interest inside the cryostat because the attenuation of the transmission line between the point of interest and the room temperature measuring device cannot be known for certain: it could only be measured indirectly, for example in a separate experiment which would introduce additional uncertainty. The transmission lines and cryogenic elements cannot be calibrated at room temperature because the properties of microwave lines and components change drastically when they are cooled down to cryogenic temperatures.
There is therefore a need for a method of measuring the absolute power of a microwave signal on a low-temperature transmission line.
According to an aspect of the invention, there is provided a quantum power sensor comprising a two-level quantum system coupled to a transmission line that supports a propagating wave.
Embodiments of the present invention can be used to measure the microwave power in any type of implementation of a transmission line, such as an uninterrupted microwave waveguide interfaced to and part of an external transmission line made out of the same or any other implementation, or as part of an interrupted (‘continuous’) transmission line supporting both partial and/or complete reflections of a propagated microwave signal. The transmission line can be of any type, including 2D and 3D waveguides and made of any material such that the transmission line supports a propagating wave. The transmission can have a wide bandwidth supporting a range of frequencies and, for example, can be a continuous 2D planar transmission line defined by metallisation on a silicon chip.
The present invention enables the measurement of power in any implementation of a transmission line by using a two-level system to yield a measurement of microwave power.
In an embodiment of the invention, the transmission line has a bandwidth of 0.5 GHz or more, desirably 1.0 GHz or more.
In an embodiment of the invention, the transmission line supports a propagating wave having a frequency in the range of from 1 to 20 GHz.
An embodiment of the invention further comprises an analyser configured to measure the coupling of the two-level system to the transmission line and the Rabi frequency of the two-level system.
In an embodiment of the invention, the analyser is a spectrum analyser or vector network analyser connected to the transmission line.
In an embodiment of the invention, the analyser is configured to operate at room temperature.
The invention also provides a measurement system comprising a quantum power sensor as described above and an object device which is to be measured.
In an embodiment of the invention, the object device is connected between the transmission line and the analyser.
In an embodiment of the invention, the analyser is connected to an input to the transmission line and the object device is connected to an output of the transmission line.
In an embodiment of the invention, the analyser is connected to the transmission line by an element with directivity.
An embodiment of the invention further comprises a power source connected to the transmission line and a control system for controlling the power source in response to the analyser.
A In an embodiment of the invention, the object device is connected to an input to the transmission line and the analyser is connected to an output of the transmission line.
An embodiment of the invention further comprises, a control source coupled to the input to the transmission line by an element with directivity.
In an embodiment of the invention, the two-level quantum system is capacitively coupled to the transmission line.
In an embodiment of the invention, the two-level quantum system is inductively coupled to the transmission line.
In an embodiment of the invention, the two-level quantum system is a system selected from the group consisting of: superconducting qubits; single-electron two-level systems; nuclear spin qubits; quantum dots; defect qubits; trapped ion qubits.
In an embodiment of the invention, the two-level quantum system and the transmission line are configured to operate at low temperatures.
The present invention also provides a method of measuring power in a transmission line, the method comprising:
coupling a two-level quantum system to the transmission line; and
determining the coupling and the Rabi frequency of the two-level system.
In an embodiment of the invention, the coupling is measured by direct transmission through the transmission line and the Rabi frequency is measured by Rabi oscillation measurements.
In an embodiment of the invention, the coupling is deduced by measuring the relative amplitude of a third and higher order mixing product and the Rabi frequency is measured by resonance fluorescence measurements.
In an embodiment of the invention, the coupling and the Rabi frequency are deduced by measuring the relative amplitude and frequency and power dependences of third and higher order mixing products as a result of driving the two-level system with two or more frequencies.
With such a construction, a measurement of absolute power at low temperature can be made by measuring a spectrum at room temperature. Although the attenuation of the circuit from the point of interest to the room temperature measurement of a spectrum is still not known, that does not matter because the spectrum shape only depends on relative power not absolute power.
Embodiments of the invention will be described below with reference to the accompanying drawings, in which:
In the Figures, like parts are indicated by like references.
An embodiment of the present invention provides a quantum system coupled to the transmission line so as to act as a quantum sensor of absolute power. The principle of operation of the invention is described further below with reference to
As shown in
Ω=μI or Ω=μV (1)
where I and V are amplitudes for an inductively or capacitively coupled two-level system 10 respectively. The dipole moment characterizes the coupling strength between the two-level system and the transmission line and therefore may be referred to as the coupling coefficient.
In an embodiment of the invention, the Rabi frequency Ω and the coupling μ of the two-level system 10 to the transmission line 20 is to be found. This pair of parameters can be obtained using different methods. For example, by measuring the coherent emission of the artificial atoms, quantum oscillation measurements may be performed to extract the Rabi frequency and the coupling can be found by measuring the transmission through the coplanar transmission line as a function of detuning δω and driving amplitude. These two quantities are sufficient to calibrate absolute power. However, coherent emission can be affected by dephasing of the artificial atoms.
To make the measurement independent of dephasing, wave scattering by means of resonance fluorescence and wave mixing can be used. The Rabi frequency can be obtained from the resonance fluorescence triplet. Under strong resonant drive the energy levels of the two-level system are split allowing the four transitions as shown in the inset of
This process is explained in more detail with reference to the proof of concept (
The two-level atom driven by a resonant microwave is described in the rotating wave approximation by the Hamiltonian
where ω0=√{square root over (ωa2−∈2)} is the anti-crossing energy between the two persistent current states, Ω=μV is the dipole interaction energy and σ±=(σx±iσy)/2 with the Pauli matrices σx, σy, σy.
The dynamics of the system are governed by the master equation
where {circumflex over (L)}[ρ]=−Γ1σzρ11−Γ2(σ+ρ10+σ−ρ01) at zero temperature, where Γ1 is the two-level system relaxation rate, solely determined by radiative emission to the line (nonradiative relaxation is negligible).
If the artificial atom is driven close to its resonance frequency ω0 it acts as a scatterer and hence generates two coherent waves propagating forward and backward with respect to the driving field:
where μ is the atomic dipole moment and Γ1 is the atomic relaxation rate with a photon emission into the line. These scattered waves are measured to deduce the power in the driving propagating wave. Solving the master equation and using Eq. 2, the stationary solution can be found:
Thus the qubit resonance reveals itself as a sharp dip in the power transmission coefficient. A power extinction 1−|t|2>85% for all qubits in the experimental setup was achieved, which shows strong coupling to the environment and hence almost all emission is emitted into the transmission line.
In order to sense the absolute power, WO, the two quantities that need to be measured are the coupling coefficient, μ, and the Rabi frequency, Ω.
The Rabi frequency can be obtained by performing quantum oscillation measurements as depicted in
The reflection coefficient is derived by measuring transmission through the coplanar line according to r=1−t.
In principle, obtaining the Rabi frequency from quantum oscillation measurements and deriving the coupling from measuring the transmission through the coplanar line is sufficient to sense the absolute power. However, potential drawbacks of this method are possible distortions at high powers in the transmission curve due to interference with leaked power. Furthermore, coherent emission is affected by dephasing. The present invention also encompasses an alternative method to attain the Rabi frequency and the coupling.
The atom coupled to a strong driving field (Ω>>Γ1) can be described by the dressed-state picture where the atomic levels are split by Ω and four transitions are allowed between the dressed states giving rise to the Mollow triplet. To observe this triplet we measure the power spectrum using a spectrum analyser at 7.48 GHz under a strong resonant drive as shown in
We deduce the Rabi frequency from the separation of the Mollow triplet side peaks and find the linear relationship between the Rabi frequency and the input microwave amplitude, as shown in
An alternative approach to acquire the coupling and Ω is to measure a side peak dependences that appears due to wave mixing processes. An analytical solution for the useful case of two close and equal frequency drives is presented below, however the solution can be generalized for arbitrary amplitudes and frequencies of the drives. The appropriate solutions can be found either analytically or numerically.
The artificial atom is driven by two continuous drives ω1=ω0+δω−Δω and ω2=ω0+δω+Δω with Δω<<Γ2. The elastic wave scattering on the artificial atom in a case when nonradiative decay is negligible (even more loose requirement than the strong coupling regime) then becomes:
with equal driving amplitudes V=V0 cos(ω0t−Δωt)+V0 cos(ω0t+Δωt) and, therefore, Ω=Ω0(eiΔωt+e−iΔωt), where Ω0=μV0. Expanding eq. 5 in series of Ω we obtain:
The expression can be simplified in the strong coupling regime when Γ2=Γ1/2, however, we present here a more general regime, accounting dephasing (Γ2>Γ1/2). By collecting the exponential terms we obtain expressions for the amplitude of the wave mixing peaks. Summing up all terms at frequency ω0+δω±(2p+1)Δω we find the analytic solution for the amplitude of ±(2p+1) peak:
The expression of eq. 7 can be further simplified to
By fitting the side peaks that appear due to wave mixing to this analytic solution (eq. 8) Ω and the coupling can be extracted thus giving enough information to sense the absolute power.
Similarly, for the more general case of unequal drive amplitudes V=V0 cos(ω0t−Δωt)+V1 cos(ω0t+Δωt), resulting in the two Rabi frequencies Ω0 and Ω1, the scattered wave amplitudes for each frequency harmonic 2p+1 is given by the general expression
where the expression is simplified by setting
In the above example, the two-level system is driven with two frequencies, however, an embodiment of the invention can use any suitable combination of frequencies. The use of multiple frequencies results in inelastic wave scattering and higher order mixing products. The incident microwave power can be deduced from the amplitude and/or phase information of these mixing products.
It can therefore be seen that a two-level system directly incorporated into a transmission line can act as a quantum sensor of absolute power by enabling a spectrum or frequency response to be correlated to power. The requirement of strong coupling can be loosened to a weak coupling (Γ2>Γ1/2) with only radiative decay to the line (negligible nonradiative relaxation). All required quantities then can be found by fitting the experimental dependences by plots of eq. 8 or eq. 9.
Various arrangements for coupling the two-level system to a transmission line are possible. By way of example,
The transmission line 20 can be any form of transmission line that supports a travelling (also referred to as a propagating) wave of suitable frequency. The transmission line can support either none, partial or full reflections of the signal at any frequency in the range 1-20 GHz at its ends. The frequency of the propagating wave may be in the range of from 1 GHz to 20 GHz. The transmission line desirably has a wide bandwidth, e.g. more than 0.5 GHz, desirably more than 1 GHz. The transmission line can be coupled to other transmission lines or other components. Desirably such coupling is impedance matched, e.g. at 50Ω, so as to minimise reflections at any transitions, but any amount of reflections can be tolerated.
The two-level system 10 can be implemented as any form of two-level quantum system that is close to resonance with the microwave signal to be measured. The device is operated in the regime where higher levels that the system may have are not excited by the signal to be measured. Examples of two-level systems that can be used in embodiments of the invention include:
An advantage of superconducting qubits is that the coupling can easily be made strong.
Example uses of the quantum power sensor of the invention are depicted in
In the arrangement of
In
To measure the output of an unknown power source or subject device 75, an arrangement such as shown in
A further arrangement to measure the power input to a transmission line or device is shown in
Embodiments of the present invention may be employed in any system that uses microwaves at cryogenic temperatures. Embodiments of the present invention can be used for determining the power delivered to or emitted from any microwave device at low temperature. A plurality of quantum power sensors according to the invention can be used to determine the power on all ports of any multi-port microwave device. Specific quantum technologies in which the invention is useful include: qubits, superconducting resonators, and circuits consisting of any number of such elements together with other on-chip microwave components such as filters, circulators. Embodiments of the present invention are also useful for calibration of coaxial cables and other transmission lines as well as cryogenic amplifiers (such as HEMTs, parametric amplifiers, travelling wave parametric amplifiers, etc.), as well as any typical microwave component intended for cryogenic use. Embodiments of the present invention may also be employed with nanoelectronic devices, other superconducting quantum devices (not qubits) and electromechanical quantum devices, as well as for materials characterisation and any other application that uses microwaves at low temperatures.
Embodiments of the present invention can be employed to measure power of microwave signals in the GHz range, for example in the range of from 1 GHz to 50 GHz. The bottom end of the frequency range to which a quantum power sensor of the present invention is sensitive, may depend on the temperature of operation. Operation at about 50 mK can enable sensitivity down to about 1 GHz. Embodiments of the invention can also be configured to operate at higher frequencies, e.g. in the THz range using different types of two-level quantum systems.
Embodiments of the present invention desirably operate at low temperatures, e.g. below about 5 K, below about 1.3 K, below about 0.5 K or below about 100 mK. The temperature of operation primarily depends on the superconducting transition temperature of any superconducting components of the two-level quantum system. High temperature superconductors and other two-level systems not based on superconductors may enable operation at higher temperature.
Having described exemplary embodiments of the invention, it will be appreciated that modifications and variations of the described embodiments can be made. For example, multiple quantum power sensors can be used in a complex system to measure power at different places in the system. The invention is not to be limited by the foregoing description but only by the appended claims.
Number | Date | Country | Kind |
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