Nothing Special   »   [go: up one dir, main page]

US20190187380A1 - Photon generator - Google Patents

Photon generator Download PDF

Info

Publication number
US20190187380A1
US20190187380A1 US16/280,144 US201916280144A US2019187380A1 US 20190187380 A1 US20190187380 A1 US 20190187380A1 US 201916280144 A US201916280144 A US 201916280144A US 2019187380 A1 US2019187380 A1 US 2019187380A1
Authority
US
United States
Prior art keywords
optical
output
optical channel
ring resonator
chip
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Abandoned
Application number
US16/280,144
Inventor
Michael L. Fanto
Paul M. Alsing
Christopher C. Tison
Stefan F. Preble
Jeffrey A. Steidle
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
US Air Force
Original Assignee
US Air Force
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by US Air Force filed Critical US Air Force
Priority to US16/280,144 priority Critical patent/US20190187380A1/en
Publication of US20190187380A1 publication Critical patent/US20190187380A1/en
Abandoned legal-status Critical Current

Links

Images

Classifications

    • GPHYSICS
    • G02OPTICS
    • G02BOPTICAL ELEMENTS, SYSTEMS OR APPARATUS
    • G02B6/00Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
    • G02B6/24Coupling light guides
    • G02B6/26Optical coupling means
    • GPHYSICS
    • G02OPTICS
    • G02BOPTICAL ELEMENTS, SYSTEMS OR APPARATUS
    • G02B6/00Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
    • G02B6/10Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type
    • G02B6/12Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type of the integrated circuit kind
    • GPHYSICS
    • G02OPTICS
    • G02FOPTICAL DEVICES OR ARRANGEMENTS FOR THE CONTROL OF LIGHT BY MODIFICATION OF THE OPTICAL PROPERTIES OF THE MEDIA OF THE ELEMENTS INVOLVED THEREIN; NON-LINEAR OPTICS; FREQUENCY-CHANGING OF LIGHT; OPTICAL LOGIC ELEMENTS; OPTICAL ANALOGUE/DIGITAL CONVERTERS
    • G02F1/00Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics
    • G02F1/01Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the intensity, phase, polarisation or colour 
    • G02F1/21Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the intensity, phase, polarisation or colour  by interference
    • G02F1/225Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the intensity, phase, polarisation or colour  by interference in an optical waveguide structure
    • GPHYSICS
    • G02OPTICS
    • G02FOPTICAL DEVICES OR ARRANGEMENTS FOR THE CONTROL OF LIGHT BY MODIFICATION OF THE OPTICAL PROPERTIES OF THE MEDIA OF THE ELEMENTS INVOLVED THEREIN; NON-LINEAR OPTICS; FREQUENCY-CHANGING OF LIGHT; OPTICAL LOGIC ELEMENTS; OPTICAL ANALOGUE/DIGITAL CONVERTERS
    • G02F1/00Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics
    • G02F1/29Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the position or the direction of light beams, i.e. deflection
    • G02F1/31Digital deflection, i.e. optical switching
    • G02F1/313Digital deflection, i.e. optical switching in an optical waveguide structure
    • G02F1/3132Digital deflection, i.e. optical switching in an optical waveguide structure of directional coupler type
    • GPHYSICS
    • G02OPTICS
    • G02FOPTICAL DEVICES OR ARRANGEMENTS FOR THE CONTROL OF LIGHT BY MODIFICATION OF THE OPTICAL PROPERTIES OF THE MEDIA OF THE ELEMENTS INVOLVED THEREIN; NON-LINEAR OPTICS; FREQUENCY-CHANGING OF LIGHT; OPTICAL LOGIC ELEMENTS; OPTICAL ANALOGUE/DIGITAL CONVERTERS
    • G02F2203/00Function characteristic
    • G02F2203/05Function characteristic wavelength dependent
    • G02F2203/055Function characteristic wavelength dependent wavelength filtering

Definitions

  • This invention relates generally to the field of quantum information processing and more specifically to integrated photonic devices that facilitate the same.
  • Micro ring resonators are becoming a key component of such systems as they have been shown to be effective as photon-pair sources by means of exploiting a materials nonlinearity for spontaneous parametric downconversion (SPDC) or spontaneous four wave mixing (SFWM).
  • SPDC spontaneous parametric downconversion
  • SFWM spontaneous four wave mixing
  • FIG. 1 depicts prior art double bus resonators which are slightly different as the photons are free to leave the ring 10 through either port—resulting in an effective loss of 50%. All of this assumes that the ring resonator is critically coupled to straight waveguides 20 , 30 .
  • the ring resonator When the ring resonator is used for generation of single photons, two different processes can occur depending on the nonlinearity of the material of the waveguide. In the case of spontaneous parametric downconversion, a single pump photon produces a photon pair, called a signal and idler. The second case is spontaneous four wave mixing where two pump photons are absorbed and two single photons are created. Both of these cases must conserve energy and momentum.
  • the single photon light which is generated inside of the cavity has no input light to interfere with. Still referring to FIG. 1 , therefore, in the case of the double bus resonator with the same coupler on input and output, the light that is generated inside the nonlinear optical material based mircroring resonator has an equal probability of exiting the first 20 and second 30 waveguide buses. This splitting is witnessed as intrinsic loss. In the case of single bus ring resonators, the light can either leave through the input port or be lost inside the ring. When the pump wavelengths are optimally coupled, the propagation losses around the ring balance with the coupling out of the ring.
  • the generated single photons (like the pumps) will have this same balance in terms of loss and ability to couple out of the ring. In other words, the single photons leave the ring only 50% of the time. The odds of the single photons leaving the ring can be improved at the cost of how well the pump wavelengths are coupled. This is a compromise between loss and generation rate.
  • a quantum computation device comprises a plurality of photon generators each have a second input and a second output; a first plurality of optical couplers, each corresponding to each of the plurality of photon generators couple the second input and the second output of the photon generator so as to produce entangled photon states; a second plurality of optical couplers, each corresponding to each of the first plurality of optical couplers; a reconfigurable optical switch network for matrixing connections between outputs of the first plurality of optical couplers and inputs of the second plurality of optical couplers; a third plurality of optical couplers, each connected to each of a corresponding second plurality of optical couplers so as to further entangle the photon states; and a plurality of photodetectors for indicating the entangled photon states output from the third plurality of optical couplers so as to facilitate computations therefrom.
  • a quantum computation device comprises a photon generator having an annular optical channel, a first linear optical channel having a first input and a first output where the first linear optical channel is substantially tangential to the annular optical channel at a first point and a second point, a second linear optical channel having a second input and a second output, where the second linear optical channel is substantially tangential to the annular optical channel at a third point and a fourth point; and a predeterminable relative phase delay between the first and the second linear optical channels so as to cause a variance in an amount of light traversing the first and the second linear optical channels as a function of the frequency of the light.
  • a quantum computation device comprises a photon generator having an annular optical channel disposed in a chip, a first linear optical channel disposed in the chip, where the channel has a first input and a first output and where the first input and a first output are in common with each other and with an input to the chip, where the first linear optical channel is substantially tangential to the annular optical channel at a first point and a second point, and where a second linear optical channel is disposed in the chip with the second linear optical channel having a second input and a second output, where the second linear optical channel is substantially tangential to the annular optical channel at a third point and a fourth point, a first predeterminable relative phase delay between the first and the second linear optical channels so as to cause a variance in an amount of light traversing the first and the second linear optical channels as a function of the frequency of said light, and a second predeterminable relative phase delay between the second input and the second output, a photon detector sampling each of the second input and the second output
  • the invention provides an apparatus for quantum computing comprising optical integrated on-chip generation of photon pairs as a building block to create entangled photon states which are detected as necessary for quantum information processing.
  • the invention provided a frequency selective optical coupling device which controls the transmission of light by varying the relative dimensions of otherwise symmetrical linear optical waveguides tangential to an annular optical waveguide, thereby controlling the coupling of light between the linear optical waveguides and the annular optical waveguide. Dimensional change of the optical waveguides is achieved by a heated medium in proximity of the optical waveguides and under electronic control.
  • the device produces entangled photons in the nonlinear optical material based ring resonator, maximizing the coupling of the pump photons, and spectrally filtering the strong pump light from the generated photon pairs.
  • the apparatus that generates the photon pairs, the dual mach-zehnder coupled ring resonator, is only a portion of the invention.
  • a similar device was used in Popovic to modulate light, though there the device was for classical applications and the photons were input from outside the device.
  • the photons that are input from outside the device only serve to add energy to produce the photon pairs that are inside the nonlinear optical material based ring resonator.
  • These photons that are now generated inside the nonlinear optical material based ring resonator are photon pairs and can be used for quantum applications.
  • FIG. 1 is a prior art double bus resonator showing the coupling coefficients to the two waveguides.
  • FIG. 2 a is a Dual Mach-Zehnder device design of the present invention.
  • FIG. 2 b is a microscope image of a fabricated Dual Mach-Zehnder device of the present invention.
  • FIG. 3 a is a Dual Mach-Zehnder theoretical spectrum showing suppressed resonances at the input side and a single transmission dip.
  • FIG. 3 b is a Dual Mach-Zehnder theoretical spectrum showing output side showing a suppressed single resonance and two resonance dips.
  • FIG. 4 is a Dual Mach-Zehnder experimentally generated spectrum showing suppressed resonances before and after tuning on both the input and output sides of the resonator.
  • FIG. 5 a is a Dual Mach-Zehnder measured photon pairs in the untuned configuration showing unwanted pairs on ports other than drop-drop, and therefore a long coincidence count rate.
  • FIG. 5 b is a Dual Mach-Zehnder measured photon pairs in the tuned configuration showing the removal of the unwanted pairs exiting the other ports, and a noticeable increase in the drop-drop port coincidence rate.
  • FIG. 6 a is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce energy-time entangled photons pairs/squeezed beams.
  • FIG. 6 b is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce energy-time entangled photons pairs/squeezed beams, further depicting interconnections to the off chip electronics.
  • FIG. 7 a is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states or pairs/squeezed beams.
  • FIG. 7 b is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states or pairs/squeezed beams, further depicting interconnections to the off chip electronics.
  • FIG. 8 a is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states and pairs/squeezed beams simultaneously.
  • FIG. 8 b is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states and pairs/squeezed beams simultaneously, further depicting interconnections to the off chip electronics.
  • FIG. 9 a is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states, frequency combs, and pairs/squeezed beams simultaneously.
  • FIG. 9 b is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states, frequency combs, and pairs/squeezed beams simultaneously, further depicting interconnections to the off chip electronics.
  • FIG. 10 is an embodiment of the present invention providing a quantum computation device employing a Dual Mach-Zehnder used to produce NOON states, frequency combs, and pairs/squeezed beams simultaneously, capable of photo detection to facilitate computation.
  • An object of the present invention is to provide a quantum computation device that utilizes a wavelength dependent means to generate correlated photon pairs and separate those pairs which are generated in nonlinear optical material based ring resonator from the pump light used to generate them.
  • the present invention employs a Dual Mach-Zehnder (MZI) device having legs that are grossly misbalanced, wherein the MZI will have a wavelength dependence to its ability to seperate the pump from the signal and idler photons.
  • the present invention devises two unbalanced MZI, one which will perfectly transmit the pump wavelengths and partially reflect the signal/idler wavelength. The other MZI will do the opposite, reflecting the pump wavelengths but perfectly transmitting the signal/idler wavelength.
  • the signal/idler are also generated inside the device via a nonlinear process, either spontaneous parametric downconversion or spontaneous four wave mixing.
  • the present invention essentially makes a a frequency selective optical coupling device having a nonlinear optical material based ring resonator in a double bus waveguide configuration where each bus waveguide connects the ring resonator at two independent points. Between these two connecting points a long waveguide section is placed to define a phase differential between the ring and the coupling arm. This creates an asymmetric Mach-Zehnder interferometer, a wavelength (frequency) selective device. Mach-Zehnder interferometer (MZI) out of the input waveguide 40 and the ring 50 .
  • MZI Mach-Zehnder interferometer
  • the nonlinear optical material based ring 50 will only support specific wavelengths of light (where the resonance condition is satisfied) separated by the free spectral range (FSR).
  • the spectrum of an unbalanced MZI is sinusoidal with the difference in optical path length between the two paths determining where in the spectrum the constructive and destructive interference will occur. For both the ring and the MZI, this is known as phase-matching. For the case of the ring this is phase-matching between consecutive round-trips while in the MZI it is phase-matching between the two different paths.
  • the points of constructive interference in the spectra of these devices can be tuned by adjusting the relative phase between the different paths. In a fabricated device (see FIG.
  • the combination of these two elements results in a phase-matching condition that relies on both the resonance condition of the ring 50 and the interference pattern of the MZI. If the spectral width between two wavelengths of constructive interference in the MZI is twice the FSR of the ring 50 , it is possible to suppress every second resonance of the ring 50 .
  • one side of the ring 50 can be used as the input 40 for the pump photons and the drop side 60 as the output for the photon pairs that are generated inside the nonlinear optical material based ring resonator.
  • the MZI on the input side 40 (MZI 1 ) can be tuned to suppress every other resonance, while MZI 2 on the output of the ring 50 can be tuned to suppress the resonances allowed by MZI 1 (i.e. they are perfectly out of phase with each other).
  • This configuration will ensure the pump laser is critically coupled into the ring 50 while not allowing it to exit out the drop port 60 , and ensures that any photons that are generated in the device at the resonances allowed by the drop port 60 will only exit the over-coupled drop port 60 (because MZI 1 is tuned to not be phased matched with those photons).
  • the input side ring is characterized by the transmission from the input port 40 to the through port 70 while the output side ring is characterized by the transmission from the add port 80 to the drop port 60 .
  • the photon pairs that are generated inside the ring according to energy and momentum conservation, with a strength corresponding to the pump intensity, nonlinear coefficient and the finesse of the ring resonator are the photons that leave on the exit port. It is crucial to note that the photons that are input to the device, the pump photons, are not the same photons that are exiting the device. The photons that exit the device are truly correlated photon pairs of which one can be detected to herald the presence of the second to produce true single photons. The theoretical spectral response for both the input and output sides are shown in FIG. 3 a and FIG. 3 b , respectively.
  • This configuration has three key features: (i) The pump is critically coupled so the photon generation rate produced inside the device will be maximized; (ii) The pump is filtered from the photons pair generated inside the device and that exit the drop port minimizing noise and reducing the amount of off-chip filtering required; (iii) The photon pairs will always leave out the same over-coupled drop port, yielding 100% coincidence ratio, maximizing heralding efficiency.
  • the theory of operation of the present invention has been experimentally proven on a fabricated device as shown in FIG. 4 .
  • the invention exhibits all the cavity resonances when the thermal tuning has not been optimized.
  • the undesirable resonances on both the input and output sides of the device are suppressed as shown in FIG. 4 .
  • This demonstrates the spectral filtering of the device (needed to remove the strong pump light from the single pairs of photons), along with the field enhancement from the ring cavity, and the directionality of the desired output for the photon pairs generated in the device shown in FIG. 5 a and FIG. 5 b . All aforesaid traits being useful for quantum information science applications.
  • the functional building block can be utilized to create entangled states when combined with other integrated waveguide circuits.
  • FIG. 6 a and FIG. 6 b concurrently depicts a dual Mach-Zehnder (DMZ) source being single or bi-directionally pumped from a continuous wave or pulsed laser source (not shown) via an optical waveguide 90 .
  • the lower diagram in FIG. 6 b , FIG. 7 b , FIG. 8 b and FIG. 9 b depicts an overlay of the off chip electronics 160 and its associated control lines 170 (dashed lines) to detection 140 and phase shifting 150 elements.
  • the pump photons interact in the nonlinear optical material based micro-ring resonator cavity 100 and produce signal/idler photons via the nonlinear process of spontaneous parametric downconversion or spontaneous four wave mixing, which exit via the optical waveguides 110 to the right of the micro-ring resonator 100 .
  • the signal/idler photons pass through phase shifters 120 which can compensate for length and timing differences before hitting an optical tap 130 where a small portion may be sent to a photodetector 140 to monitor the photons.
  • the other ports 180 allows the photon pairs/squeezed beams to pass to the rest of the circuit on the integrated chip or leave off chip.
  • the device is controlled by off chip electronics 160 , with electrical control lines 170 being depicted as dashed lines in each of FIG.
  • Heater mechanisms 150 designated in FIG. 6 through FIG. 10 as wide, solid black sections comprise material that is placed alongside optical waveguide within the DMZ. When activated by the off chip electronics, the heater mechanisms 150 heat the adjacent optical waveguide, causing a dimensional change in the optical waveguide. The optical dimensional change insofar as the optical waveguide length is affected will cause a phase shift for any light therein. The net desired effect is to alter the relative optical lengths between the upper and lower waveguides and the optical length of the ring resonator 100 within the DMZ.
  • FIG. 7 a and FIG. 7 b concurrently depicts DMZ source being pumped bi-directionally from a laser (continuous wave or pulsed) via an optical waveguide 90 .
  • the pump photons interact in the ring resonator 100 and produce signal/idler photons via the nonlinear process of spontaneous parametric downconversion or spontaneous four wave mixing, in both clockwise and counter-clockwise directions, thus producing path indistinguishable photons created in the ring 100 .
  • These photons then exit via the optical waveguides 110 to the right of the ring.
  • the signal/idler photons pass through phase shifters 120 which can compensate for length and timing differences before simultaneously impinging on a directional coupler 190 .
  • Directional coupler 190 is formed from one linear optical channel 220 connected between one of the phase shifters 120 and the corresponding optical tap 130 , and another linear optical channel 230 connected between one of the phase shifters 120 and the corresponding optical tap 130 .
  • the two linear channels 220 , 230 are substantially tangential at one point along their approximate mid-length. It is at this substantially tangential point that light is free to couple from one of the two linear optical channels to the other, thereby producing a coupling effect.
  • the resultant coupler 190 mixes the photon states producing an entangled state called a NOON state, or N photon, Zero, Zero, N photon state.
  • the other ports 180 allows the photons to pass to the rest of the circuit on the integrated chip or leave off chip.
  • the circuit can be utilized to produce not only NOON states but also qudit states for the other portions of the frequency comb that is produced.
  • FIG. 8 a and FIG. 8 b concurrently depicts DMZ source being pumped bi-directionally from a laser (continuous wave or pulsed) via an optical waveguide 90 .
  • the pump photons interact in the ring resonator cavity 100 and produce signal/idler photons via the nonlinear process of spontaneous parametric downconversion or spontaneous four wave mixing, in both clockwise and counter-clockwise directions, thus producing path indistinguishable photons created in the ring resonator 100 .
  • These photons then exit via the optical waveguides 110 to the right of the ring resonator 100 .
  • the spectrally degenerate photons are selected by an optical ring resonator filter 200 and pass through phase shifters 120 which can compensate for length and timing differences before impinging on a directional coupler 190 .
  • This coupler 190 mixes the photon states producing an entangled state called a NOON state, or N photon, Zero, Zero, N photon state.
  • the state exists the coupler 190 and passes to the rest of the circuit on the integrated chip or leave off chip.
  • the photons that are not selected by the filter 200 travel on a different waveguide, passing through a phase shifter 120 and then hitting an optical tap 130 .
  • This resonant comb of other wavelengths can be monitored with a photodetector 140 or passed to other circuitry to be utilized elsewhere.
  • This source shown in FIG. 8 a and FIG. 8 b , can then produce NOON states, entangled frequency combs, and or squeezed states simultaneously.
  • the DMZ source is pumped bi-directionally from a laser (continuous wave or pulsed) via an optical waveguide 90 .
  • the pump photons interact in the ring resonator cavity 100 and produce signal/idler photons via the nonlinear process of spontaneous parametric downconversion or spontaneous four wave mixing, in both clockwise and counter-clockwise directions, thus producing path indistinguishable photons created in the ring resonator 100 .
  • These photons then exit via the optical waveguides 110 to the right of the ring resonator 100 .
  • the spectrally degenerate photons are selected by an optical ring resonator filter 200 and pass through phase shifters 120 which can compensate for length and timing differences before impinging on a directional coupler 190 .
  • This coupler 190 mixes the photon states producing an entangled state called a NOON state, or N photon, Zero, Zero, N photon state.
  • the state exits the coupler 190 and passes to the rest of the circuit on the integrated chip or leave off chip to other circuits.
  • the photons that are not selected by the ring resonator filter 200 travel on a different waveguide, passing through a phase shifter 120 followed by two additional filters 210 . These two secondary filters 210 can serve a number of functions.
  • They can further filter the pump wavelength to allow for a filtered set of photons to leave on the original waveguide. They can each filter out a different set of wavelengths to produce more correlated outputs, one on each set of filter outputs and letting the rest of the comb exit on the original waveguide when multiple correlated photon pair outputs are required.
  • This source can then produce NOON states, multiple energy-time correlated pairs/squeezed beams, entangled combs, and squeezed states simultaneously.
  • FIG. 10 depicts the DMZ source being pumped bi-directionally from a laser (continuous wave or pulsed) via an optical waveguide 90 .
  • the pump photons interact in the ring resonator cavity 100 producing signal/idler photons via the nonlinear process of spontaneous parametric downconversion or spontaneous four wave mixing, in both clockwise and counter-clockwise directions, thus producing path indistinguishable photons created in the ring resonator 100 .
  • These photons then exit via the optical waveguides to the right of the ring resonator 100 .
  • the signal/idler photons pass through phase shifters 120 which can compensate for length and timing differences before simultaneously impinging on a directional coupler 190 .
  • coupler 190 which mixes the photon states producing an entangled state called a NOON state, or N photon, Zero, Zero, N photon state.
  • the state exits the coupler 190 and passes to a switching network which in one implementation could consist of Mach-Zehnder interferometers (MZI).
  • MZI Mach-Zehnder interferometers
  • These MZI's mix the photon states in a reconfigurable manner that allows the creation of entangled states. These can range from two photon (Bell states) to larger entangled states (Cluster and Greene-Horne-Zeilinger (GHZ) states).
  • the circuit can be used to produce states important for small scale quantum information processing, specifically quantum computation.
  • the optical waveguides can terminate with photodetectors 140 allowing the entire computation to be completed on chip.
  • the invention produces larger entangled photon states.
  • the invention would be the quantum equivalent of an FPGA (field programmable gate array) in classical computing, thus one advantage is the reconfigurability.
  • the invention functions in the following way, a pump laser is input to optical waveguide 90 , and travels to ring 100 . Inside ring 100 , the pump laser's photons are converted into pairs of photons which are correlated, or twin photons. Due to the design of the optical waveguide 90 , connecting to the ring 100 , only the twin photons enter the two phase shifters 120 , while the pump laser light remains in ring 100 . These twin photons traveling through 120 experience a phase shift and interfere at directional coupler 190 .
  • correlated photons are entangled and can be used as quantum bits for computation. All this occurs in only one section of the invention from 90 , to 100 , to 120 , to 190 . Ideally for real computations more than two quantum bits are required, so the necessary components 90 , 100 , 120 , and 190 are repeated in an array from 1 to n. To allow all of these different sources to become entangled, through interference, and function together a large array of these interferometers are required, made of components 190 , 120 , and 190 .
  • the required grid of interferometers is n ⁇ n, where n is number of waveguides exiting all the rings 100 .
  • Encoding via interference and phase shifts via 120 are imprinted on the channels to create larger quantum states or enact a calculation.
  • the result of these changes can be measured via a photodetector 140 , and the results are recorded via electronics.
  • This invention would be one incarnation of a photonic processor for quantum computation. This device allows for the generation of large entangled states in a reconfigurable fashion due to the mesh network of interferometers.
  • the dual mach zehnder photon source, 90 & 100 allows for on chip filtering of the pump laser, something not done before in a source. This source also allows for the use of a single integrated chip as most systems would need to filter the pump light off chip before going to the interferometric mesh network.
  • the dual mach zehnder design allows for controlled directionality of the twin photons, which are the required quantity needed for computation (these are the quantum bits).
  • Traditional sources lose 50% of these twins just from their source design. Therefore the dual mach zehnder source allows for a reduction in the required pump laser power compared to other sources. This makes the overall device more efficient.

Landscapes

  • Physics & Mathematics (AREA)
  • Nonlinear Science (AREA)
  • General Physics & Mathematics (AREA)
  • Optics & Photonics (AREA)
  • Engineering & Computer Science (AREA)
  • Microelectronics & Electronic Packaging (AREA)
  • Optical Modulation, Optical Deflection, Nonlinear Optics, Optical Demodulation, Optical Logic Elements (AREA)
  • Optical Integrated Circuits (AREA)

Abstract

Briefly stated, the invention provides an apparatus for quantum computing comprising optical integrated on-chip generation of photon pairs as building blocks to create entangled photon states which are detected as necessary for quantum information processing. The invention provided a frequency selective optical coupling device which controls the transmission of light by varying the relative dimensions of otherwise symmetrical linear optical waveguides tangential to an annular optical waveguide, thereby controlling the coupling of light between the linear optical waveguides and the annular optical waveguide. Dimensional change of the optical waveguides is achieved by a heated medium in proximity of the optical waveguides and under electronic control.

Description

    RELATIONSHIP TO OTHER PENDING APPLICATIONS
  • This patent application is a continuation of, cross references, and claims any and all priority benefit from U.S. patent application Ser. No. 15/833,274 filed on Dec. 6, 2017, now pending and incorporated by reference as if fully set forth herein.
  • U.S. patent application Ser. No. 15/833,274 cross references and claims the priority benefit under 35 USC § 119(e) of the filing date of provisional application Ser. No. 62/424,739 having been filed in the United States Patent and Trademark Office on Nov. 21, 2016 and now incorporated by reference as if fully set forth herein.
  • STATEMENT OF GOVERNMENT INTEREST
  • The invention described herein may be manufactured and used by or for the Government for governmental purposes without the payment of any royalty thereon.
  • TECHNICAL FIELD OF THE INVENTION
  • This invention relates generally to the field of quantum information processing and more specifically to integrated photonic devices that facilitate the same.
  • BACKGROUND OF THE INVENTION
  • Integrated photonics is proving to be a very promising platform for quantum information processing. Micro ring resonators are becoming a key component of such systems as they have been shown to be effective as photon-pair sources by means of exploiting a materials nonlinearity for spontaneous parametric downconversion (SPDC) or spontaneous four wave mixing (SFWM).
  • Often, it is desirable to have precisely one photon. While SPDC and SFWM sources generate pairs of photons, single photons can be achieved through heralding. Heralding is a technique in which the detection of a single photon from a pair is used to determine the existence of the other. One of the fundamental issues with ring resonators is their inherent 50% loss when critically coupled, regardless of operation in a single bus or double bus configuration. For single bus resonators (not shown), half of the generated photons are lost to scattering within the cavity.
  • Referring to FIG. 1 depicts prior art double bus resonators which are slightly different as the photons are free to leave the ring 10 through either port—resulting in an effective loss of 50%. All of this assumes that the ring resonator is critically coupled to straight waveguides 20, 30.
  • As with the two typical forms of ring resonators, they are denoted by the number of waveguides coupled to them giving them the titles of single bus and double bus, respectively. Both resonators work on the same principle. When light after a full round trip around the ring is of equal intensity and opposite phase to light that is reflecting into the ring, there is a destructive interference and no light can leave the resonator. Running time in reverse and seeing the light from the ring split at the directional coupler is an equivalent way to view this effect. In the case of the single bus resonator with no loss, resonance can only happen for a coupling ratio of 50/50 from the bus waveguide. When loss is present, this can happen for much lower splitting ratios. One form that loss can take is scattering. The double bus resonator can be seen as a special case of the single bus resonator where the scattering is captured into the second waveguide.
  • When the ring resonator is used for generation of single photons, two different processes can occur depending on the nonlinearity of the material of the waveguide. In the case of spontaneous parametric downconversion, a single pump photon produces a photon pair, called a signal and idler. The second case is spontaneous four wave mixing where two pump photons are absorbed and two single photons are created. Both of these cases must conserve energy and momentum.
  • Consequentially, the single photon light which is generated inside of the cavity has no input light to interfere with. Still referring to FIG. 1, therefore, in the case of the double bus resonator with the same coupler on input and output, the light that is generated inside the nonlinear optical material based mircroring resonator has an equal probability of exiting the first 20 and second 30 waveguide buses. This splitting is witnessed as intrinsic loss. In the case of single bus ring resonators, the light can either leave through the input port or be lost inside the ring. When the pump wavelengths are optimally coupled, the propagation losses around the ring balance with the coupling out of the ring. The generated single photons (like the pumps) will have this same balance in terms of loss and ability to couple out of the ring. In other words, the single photons leave the ring only 50% of the time. The odds of the single photons leaving the ring can be improved at the cost of how well the pump wavelengths are coupled. This is a compromise between loss and generation rate.
  • The underlying issue of single and double bus ring resonators is that they do not have wavelength discriminating couplers. It is well understood there doesn't exist dichroic mirrors on a chip presently. Moreover, in 1995, Barbarossa found that resonant wavelengths of a micro ring cavity could theoretically be suppressed by coupling the input waveguide to the ring at two points. However Barbarossa's design provided an optical filter for classical light without generating any photons in the resonator cavity. What is lacking in prior work and therefore still needed is a device that generates entangled pairs of photons and interferometric coupling as a filter for quantum states of light.
  • OBJECTS AND SUMMARY OF THE INVENTION
  • It is therefore a primary object of the present invention to provide an apparatus and method to generate and detect entangled pairs of photons for use in quantum information processing.
  • It is another object of the present invention to provide an integrated photonic apparatus and method that generates entangled pairs of photons.
  • A fundamental embodiment of the present invention, a quantum computation device, comprises a plurality of photon generators each have a second input and a second output; a first plurality of optical couplers, each corresponding to each of the plurality of photon generators couple the second input and the second output of the photon generator so as to produce entangled photon states; a second plurality of optical couplers, each corresponding to each of the first plurality of optical couplers; a reconfigurable optical switch network for matrixing connections between outputs of the first plurality of optical couplers and inputs of the second plurality of optical couplers; a third plurality of optical couplers, each connected to each of a corresponding second plurality of optical couplers so as to further entangle the photon states; and a plurality of photodetectors for indicating the entangled photon states output from the third plurality of optical couplers so as to facilitate computations therefrom.
  • Still in a fundamental embodiment of the present invention, a quantum computation device, comprises a photon generator having an annular optical channel, a first linear optical channel having a first input and a first output where the first linear optical channel is substantially tangential to the annular optical channel at a first point and a second point, a second linear optical channel having a second input and a second output, where the second linear optical channel is substantially tangential to the annular optical channel at a third point and a fourth point; and a predeterminable relative phase delay between the first and the second linear optical channels so as to cause a variance in an amount of light traversing the first and the second linear optical channels as a function of the frequency of the light.
  • In the preferred embodiment of the present invention, a quantum computation device, comprises a photon generator having an annular optical channel disposed in a chip, a first linear optical channel disposed in the chip, where the channel has a first input and a first output and where the first input and a first output are in common with each other and with an input to the chip, where the first linear optical channel is substantially tangential to the annular optical channel at a first point and a second point, and where a second linear optical channel is disposed in the chip with the second linear optical channel having a second input and a second output, where the second linear optical channel is substantially tangential to the annular optical channel at a third point and a fourth point, a first predeterminable relative phase delay between the first and the second linear optical channels so as to cause a variance in an amount of light traversing the first and the second linear optical channels as a function of the frequency of said light, and a second predeterminable relative phase delay between the second input and the second output, a photon detector sampling each of the second input and the second output, and a third output of the chip in common with the second input, a fourth output of the chip in common with the second output, and an electronic control subsystem in operative communication with the chip for facilitating the predeterminable relative phase delays and the photon detection.
  • Briefly stated, the invention provides an apparatus for quantum computing comprising optical integrated on-chip generation of photon pairs as a building block to create entangled photon states which are detected as necessary for quantum information processing. The invention provided a frequency selective optical coupling device which controls the transmission of light by varying the relative dimensions of otherwise symmetrical linear optical waveguides tangential to an annular optical waveguide, thereby controlling the coupling of light between the linear optical waveguides and the annular optical waveguide. Dimensional change of the optical waveguides is achieved by a heated medium in proximity of the optical waveguides and under electronic control. The device produces entangled photons in the nonlinear optical material based ring resonator, maximizing the coupling of the pump photons, and spectrally filtering the strong pump light from the generated photon pairs. The apparatus that generates the photon pairs, the dual mach-zehnder coupled ring resonator, is only a portion of the invention. A similar device was used in Popovic to modulate light, though there the device was for classical applications and the photons were input from outside the device. In this invention the photons that are input from outside the device only serve to add energy to produce the photon pairs that are inside the nonlinear optical material based ring resonator. These photons that are now generated inside the nonlinear optical material based ring resonator are photon pairs and can be used for quantum applications.
  • BRIEF DESCRIPTION OF THE DRAWINGS
  • FIG. 1 is a prior art double bus resonator showing the coupling coefficients to the two waveguides.
  • FIG. 2a is a Dual Mach-Zehnder device design of the present invention.
  • FIG. 2b is a microscope image of a fabricated Dual Mach-Zehnder device of the present invention.
  • FIG. 3a is a Dual Mach-Zehnder theoretical spectrum showing suppressed resonances at the input side and a single transmission dip.
  • FIG. 3b is a Dual Mach-Zehnder theoretical spectrum showing output side showing a suppressed single resonance and two resonance dips.
  • FIG. 4 is a Dual Mach-Zehnder experimentally generated spectrum showing suppressed resonances before and after tuning on both the input and output sides of the resonator.
  • FIG. 5a is a Dual Mach-Zehnder measured photon pairs in the untuned configuration showing unwanted pairs on ports other than drop-drop, and therefore a long coincidence count rate.
  • FIG. 5b is a Dual Mach-Zehnder measured photon pairs in the tuned configuration showing the removal of the unwanted pairs exiting the other ports, and a noticeable increase in the drop-drop port coincidence rate.
  • FIG. 6a is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce energy-time entangled photons pairs/squeezed beams.
  • FIG. 6b is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce energy-time entangled photons pairs/squeezed beams, further depicting interconnections to the off chip electronics.
  • FIG. 7a is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states or pairs/squeezed beams.
  • FIG. 7b is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states or pairs/squeezed beams, further depicting interconnections to the off chip electronics.
  • FIG. 8a is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states and pairs/squeezed beams simultaneously.
  • FIG. 8b is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states and pairs/squeezed beams simultaneously, further depicting interconnections to the off chip electronics.
  • FIG. 9a is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states, frequency combs, and pairs/squeezed beams simultaneously.
  • FIG. 9b is an embodiment of the present invention employing a Dual Mach-Zehnder used to produce NOON states, frequency combs, and pairs/squeezed beams simultaneously, further depicting interconnections to the off chip electronics.
  • FIG. 10 is an embodiment of the present invention providing a quantum computation device employing a Dual Mach-Zehnder used to produce NOON states, frequency combs, and pairs/squeezed beams simultaneously, capable of photo detection to facilitate computation.
  • DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
  • An object of the present invention is to provide a quantum computation device that utilizes a wavelength dependent means to generate correlated photon pairs and separate those pairs which are generated in nonlinear optical material based ring resonator from the pump light used to generate them. The present invention employs a Dual Mach-Zehnder (MZI) device having legs that are grossly misbalanced, wherein the MZI will have a wavelength dependence to its ability to seperate the pump from the signal and idler photons. The present invention devises two unbalanced MZI, one which will perfectly transmit the pump wavelengths and partially reflect the signal/idler wavelength. The other MZI will do the opposite, reflecting the pump wavelengths but perfectly transmitting the signal/idler wavelength. The signal/idler are also generated inside the device via a nonlinear process, either spontaneous parametric downconversion or spontaneous four wave mixing.
  • Referring to FIG. 2a and FIG. 2b , the present invention essentially makes a a frequency selective optical coupling device having a nonlinear optical material based ring resonator in a double bus waveguide configuration where each bus waveguide connects the ring resonator at two independent points. Between these two connecting points a long waveguide section is placed to define a phase differential between the ring and the coupling arm. This creates an asymmetric Mach-Zehnder interferometer, a wavelength (frequency) selective device. Mach-Zehnder interferometer (MZI) out of the input waveguide 40 and the ring 50. Being a cavity, the nonlinear optical material based ring 50 will only support specific wavelengths of light (where the resonance condition is satisfied) separated by the free spectral range (FSR). The spectrum of an unbalanced MZI is sinusoidal with the difference in optical path length between the two paths determining where in the spectrum the constructive and destructive interference will occur. For both the ring and the MZI, this is known as phase-matching. For the case of the ring this is phase-matching between consecutive round-trips while in the MZI it is phase-matching between the two different paths. The points of constructive interference in the spectra of these devices can be tuned by adjusting the relative phase between the different paths. In a fabricated device (see FIG. 2b ) this can be accomplished by heaters or electro-optic phase shifters. The combination of these two elements results in a phase-matching condition that relies on both the resonance condition of the ring 50 and the interference pattern of the MZI. If the spectral width between two wavelengths of constructive interference in the MZI is twice the FSR of the ring 50, it is possible to suppress every second resonance of the ring 50.
  • For the case of the photon-pair source function of the present invention, one side of the ring 50 can be used as the input 40 for the pump photons and the drop side 60 as the output for the photon pairs that are generated inside the nonlinear optical material based ring resonator. The MZI on the input side 40 (MZI1) can be tuned to suppress every other resonance, while MZI2 on the output of the ring 50 can be tuned to suppress the resonances allowed by MZI1 (i.e. they are perfectly out of phase with each other). This configuration will ensure the pump laser is critically coupled into the ring 50 while not allowing it to exit out the drop port 60, and ensures that any photons that are generated in the device at the resonances allowed by the drop port 60 will only exit the over-coupled drop port 60 (because MZI1 is tuned to not be phased matched with those photons). This makes the device function as though it is two independent single bus ring resonators, one for the input side and one for the output side. The input side ring is characterized by the transmission from the input port 40 to the through port 70 while the output side ring is characterized by the transmission from the add port 80 to the drop port 60. The photon pairs that are generated inside the ring according to energy and momentum conservation, with a strength corresponding to the pump intensity, nonlinear coefficient and the finesse of the ring resonator are the photons that leave on the exit port. It is crucial to note that the photons that are input to the device, the pump photons, are not the same photons that are exiting the device. The photons that exit the device are truly correlated photon pairs of which one can be detected to herald the presence of the second to produce true single photons. The theoretical spectral response for both the input and output sides are shown in FIG. 3a and FIG. 3b , respectively. This configuration has three key features: (i) The pump is critically coupled so the photon generation rate produced inside the device will be maximized; (ii) The pump is filtered from the photons pair generated inside the device and that exit the drop port minimizing noise and reducing the amount of off-chip filtering required; (iii) The photon pairs will always leave out the same over-coupled drop port, yielding 100% coincidence ratio, maximizing heralding efficiency.
  • The theory of operation of the present invention has been experimentally proven on a fabricated device as shown in FIG. 4. The invention exhibits all the cavity resonances when the thermal tuning has not been optimized. When the thermal tuning has been adjusted the undesirable resonances on both the input and output sides of the device are suppressed as shown in FIG. 4. This demonstrates the spectral filtering of the device (needed to remove the strong pump light from the single pairs of photons), along with the field enhancement from the ring cavity, and the directionality of the desired output for the photon pairs generated in the device shown in FIG. 5a and FIG. 5b . All aforesaid traits being useful for quantum information science applications.
  • With the confirmation of the dual Mach-Zehnder configuration as an optimal design for the generation of maximally bright, pump filtered, directionalized photon pairs, larger photon pair states, and higher squeezed states, the functional building block can be utilized to create entangled states when combined with other integrated waveguide circuits.
  • Detailed below are five different implementations of the present invention built with the dual mach-zehnder photon pairs generation source built into the circuit for use in quantum information science applications. These are not the only implementations that this device can be configured in for these applications. The invention as stated can be used to generate, photon pairs, entangled states, larger entangled states (cluster states, GHZ states, W states, etc.), and higher squeezed states (for continuous variable applications). All embodiments of the present invention described below can be utilized to generate any of these mentioned photon states. Lastly another benefit of the invention is that the source acts as filter for the pump light. This is an easy problem to deal with in bulk optics, but in integrated circuits, removing the pump is difficult since high rejection filters are required on chip to deal with ˜10 orders of magnitude difference in pump to signal/idler power. The present invention takes care of a large portion of this filtering.
  • Referring now to FIG. 6a and FIG. 6b concurrently depicts a dual Mach-Zehnder (DMZ) source being single or bi-directionally pumped from a continuous wave or pulsed laser source (not shown) via an optical waveguide 90. The lower diagram in FIG. 6b , FIG. 7b , FIG. 8b and FIG. 9b depicts an overlay of the off chip electronics 160 and its associated control lines 170 (dashed lines) to detection 140 and phase shifting 150 elements.
  • The pump photons interact in the nonlinear optical material based micro-ring resonator cavity 100 and produce signal/idler photons via the nonlinear process of spontaneous parametric downconversion or spontaneous four wave mixing, which exit via the optical waveguides 110 to the right of the micro-ring resonator 100. The signal/idler photons pass through phase shifters 120 which can compensate for length and timing differences before hitting an optical tap 130 where a small portion may be sent to a photodetector 140 to monitor the photons. The other ports 180 allows the photon pairs/squeezed beams to pass to the rest of the circuit on the integrated chip or leave off chip. The device is controlled by off chip electronics 160, with electrical control lines 170 being depicted as dashed lines in each of FIG. 6 through FIG. 9. Part of what the off chip electronics 160 controls are the “heater” mechanisms 150. Heater mechanisms 150 designated in FIG. 6 through FIG. 10 as wide, solid black sections comprise material that is placed alongside optical waveguide within the DMZ. When activated by the off chip electronics, the heater mechanisms 150 heat the adjacent optical waveguide, causing a dimensional change in the optical waveguide. The optical dimensional change insofar as the optical waveguide length is affected will cause a phase shift for any light therein. The net desired effect is to alter the relative optical lengths between the upper and lower waveguides and the optical length of the ring resonator 100 within the DMZ. The circuit that is shown in FIG. 6 utilizes the DMZ to produce a frequency comb of entangled photon pairs or when operated in the bright pair regime will produce a comb of entangled squeezed light beams separated by a cavity free spectral range. This allows in both cases the quantum equivalent of a dense wavelength division photon source in a single device.
  • Referring now to FIG. 7a and FIG. 7b concurrently depicts DMZ source being pumped bi-directionally from a laser (continuous wave or pulsed) via an optical waveguide 90. The pump photons interact in the ring resonator 100 and produce signal/idler photons via the nonlinear process of spontaneous parametric downconversion or spontaneous four wave mixing, in both clockwise and counter-clockwise directions, thus producing path indistinguishable photons created in the ring 100. These photons then exit via the optical waveguides 110 to the right of the ring. The signal/idler photons pass through phase shifters 120 which can compensate for length and timing differences before simultaneously impinging on a directional coupler 190. Directional coupler 190 is formed from one linear optical channel 220 connected between one of the phase shifters 120 and the corresponding optical tap 130, and another linear optical channel 230 connected between one of the phase shifters 120 and the corresponding optical tap 130. The two linear channels 220, 230 are substantially tangential at one point along their approximate mid-length. It is at this substantially tangential point that light is free to couple from one of the two linear optical channels to the other, thereby producing a coupling effect. The resultant coupler 190 mixes the photon states producing an entangled state called a NOON state, or N photon, Zero, Zero, N photon state. The state exits the coupler 190 and passes to an optical tap 130 where a small portion may be sent to a detector 140 to monitor the photons. The other ports 180 allows the photons to pass to the rest of the circuit on the integrated chip or leave off chip. The circuit can be utilized to produce not only NOON states but also qudit states for the other portions of the frequency comb that is produced.
  • Referring now to FIG. 8a and FIG. 8b concurrently depicts DMZ source being pumped bi-directionally from a laser (continuous wave or pulsed) via an optical waveguide 90. The pump photons interact in the ring resonator cavity 100 and produce signal/idler photons via the nonlinear process of spontaneous parametric downconversion or spontaneous four wave mixing, in both clockwise and counter-clockwise directions, thus producing path indistinguishable photons created in the ring resonator 100. These photons then exit via the optical waveguides 110 to the right of the ring resonator 100. The spectrally degenerate photons are selected by an optical ring resonator filter 200 and pass through phase shifters 120 which can compensate for length and timing differences before impinging on a directional coupler 190. This coupler 190 mixes the photon states producing an entangled state called a NOON state, or N photon, Zero, Zero, N photon state. The state exists the coupler 190 and passes to the rest of the circuit on the integrated chip or leave off chip. The photons that are not selected by the filter 200 travel on a different waveguide, passing through a phase shifter 120 and then hitting an optical tap 130. This resonant comb of other wavelengths can be monitored with a photodetector 140 or passed to other circuitry to be utilized elsewhere. This source, shown in FIG. 8a and FIG. 8b , can then produce NOON states, entangled frequency combs, and or squeezed states simultaneously.
  • Referring to FIG. 9a and FIG. 9b concurrently depicts The DMZ source is pumped bi-directionally from a laser (continuous wave or pulsed) via an optical waveguide 90. The pump photons interact in the ring resonator cavity 100 and produce signal/idler photons via the nonlinear process of spontaneous parametric downconversion or spontaneous four wave mixing, in both clockwise and counter-clockwise directions, thus producing path indistinguishable photons created in the ring resonator 100. These photons then exit via the optical waveguides 110 to the right of the ring resonator 100. The spectrally degenerate photons are selected by an optical ring resonator filter 200 and pass through phase shifters 120 which can compensate for length and timing differences before impinging on a directional coupler 190. This coupler 190 mixes the photon states producing an entangled state called a NOON state, or N photon, Zero, Zero, N photon state. The state exits the coupler 190 and passes to the rest of the circuit on the integrated chip or leave off chip to other circuits. The photons that are not selected by the ring resonator filter 200 travel on a different waveguide, passing through a phase shifter 120 followed by two additional filters 210. These two secondary filters 210 can serve a number of functions. They can further filter the pump wavelength to allow for a filtered set of photons to leave on the original waveguide. They can each filter out a different set of wavelengths to produce more correlated outputs, one on each set of filter outputs and letting the rest of the comb exit on the original waveguide when multiple correlated photon pair outputs are required. This source can then produce NOON states, multiple energy-time correlated pairs/squeezed beams, entangled combs, and squeezed states simultaneously.
  • Referring to FIG. 10 depicts the DMZ source being pumped bi-directionally from a laser (continuous wave or pulsed) via an optical waveguide 90. The pump photons interact in the ring resonator cavity 100 producing signal/idler photons via the nonlinear process of spontaneous parametric downconversion or spontaneous four wave mixing, in both clockwise and counter-clockwise directions, thus producing path indistinguishable photons created in the ring resonator 100. These photons then exit via the optical waveguides to the right of the ring resonator 100. The signal/idler photons pass through phase shifters 120 which can compensate for length and timing differences before simultaneously impinging on a directional coupler 190. These partially spectrally filtered (pump not fully rejected) signal/idler photons enter coupler 190 which mixes the photon states producing an entangled state called a NOON state, or N photon, Zero, Zero, N photon state. The state exits the coupler 190 and passes to a switching network which in one implementation could consist of Mach-Zehnder interferometers (MZI). These MZI's mix the photon states in a reconfigurable manner that allows the creation of entangled states. These can range from two photon (Bell states) to larger entangled states (Cluster and Greene-Horne-Zeilinger (GHZ) states). The circuit can be used to produce states important for small scale quantum information processing, specifically quantum computation. The optical waveguides can terminate with photodetectors 140 allowing the entire computation to be completed on chip.
  • Still referring to FIG. 10, the invention produces larger entangled photon states. The invention would be the quantum equivalent of an FPGA (field programmable gate array) in classical computing, thus one advantage is the reconfigurability. The invention functions in the following way, a pump laser is input to optical waveguide 90, and travels to ring 100. Inside ring 100, the pump laser's photons are converted into pairs of photons which are correlated, or twin photons. Due to the design of the optical waveguide 90, connecting to the ring 100, only the twin photons enter the two phase shifters 120, while the pump laser light remains in ring 100. These twin photons traveling through 120 experience a phase shift and interfere at directional coupler 190. These correlated photons are entangled and can be used as quantum bits for computation. All this occurs in only one section of the invention from 90, to 100, to 120, to 190. Ideally for real computations more than two quantum bits are required, so the necessary components 90, 100, 120, and 190 are repeated in an array from 1 to n. To allow all of these different sources to become entangled, through interference, and function together a large array of these interferometers are required, made of components 190, 120, and 190. The required grid of interferometers is n×n, where n is number of waveguides exiting all the rings 100. Encoding via interference and phase shifts via 120, are imprinted on the channels to create larger quantum states or enact a calculation. The result of these changes can be measured via a photodetector 140, and the results are recorded via electronics. This invention would be one incarnation of a photonic processor for quantum computation. This device allows for the generation of large entangled states in a reconfigurable fashion due to the mesh network of interferometers.
  • The dual mach zehnder photon source, 90 & 100, allows for on chip filtering of the pump laser, something not done before in a source. This source also allows for the use of a single integrated chip as most systems would need to filter the pump light off chip before going to the interferometric mesh network.
  • The dual mach zehnder design allows for controlled directionality of the twin photons, which are the required quantity needed for computation (these are the quantum bits). Traditional sources lose 50% of these twins just from their source design. Therefore the dual mach zehnder source allows for a reduction in the required pump laser power compared to other sources. This makes the overall device more efficient.
  • Having described preferred embodiments of the invention with reference to the accompanying drawings, it is to be understood that the invention is not limited to those precise embodiments, and that various changes and modifications may be effected therein by one skilled in the art without departing from the scope or spirit of the invention as defined in the appended claims.

Claims (13)

What is claimed is:
1. A quantum computation device, comprising:
a plurality of photon generators, each
photon generator further comprising:
a ring resonator disposed in a chip;
a first optical channel disposed in said chip, said first optical channel having a first input and a first output, said first input and said first output being in common with each other and with said input to said chip;
said first optical channel being tangential to said ring resonator at a first point and a second point; and
a second optical channel disposed in said chip, said second optical channel having a second input and a second output;
said second optical channel being tangential to said ring resonator at a third point and a fourth point;
a first plurality of optical couplers, each optical coupler corresponding to one of said plurality of photon generators in a one-to-one fashion for coupling said second input and said second output of said photon generator so as to produce entangled photon states;
a reconfigurable optical switch network for matrixing connections between outputs of said first plurality of optical couplers and inputs of a second plurality of optical couplers;
a second plurality of optical couplers, each corresponding to and each being reconfigurably connected via said reconfigurable optical switch network to any one of said first plurality of optical couplers;
a third plurality of optical couplers, each connected to each of a corresponding second plurality of optical couplers so as to further entangle said photon states;
phase shifting elements
between each of said plurality of photon generators and each of said corresponding first plurality of optical couplers; and
between each of said second plurality of optical couplers and each of said corresponding third plurality of optical couplers so as to compensate for optical length and timing differences; and
a plurality of photodetectors for indicating said entangled photon states output from said third plurality of optical couplers so as to facilitate computations therefrom.
2. (canceled)
3. (canceled)
4. The quantum computation device of claim 1, wherein said photon generators each further comprise:
a first filter having an output for selecting spectrally degenerate photons from said second input of said second optical channel;
a second filter having an output for selecting spectrally degenerate photons from said second output of said second optical channel;
a first predeterminable relative phase delay between said first optical channel and said second optical channel, so as to cause a variance in an amount of light traversing said first optical channel and said second optical channel as a function of the frequency of said light;
a second predeterminable relative phase delay between said second input of said second optical channel and said second output of said second optical channel;
at least one filter of a third filter group having an output in common with a first output of said plurality of outputs of said chip, where said at least one filter of said third filter group selects predetermined wavelengths of light from said phase delayed second input of said second optical channel;
at least one filter of a fourth filter group each having an output in common with a second output of said plurality of outputs of said chip, where said at least one filter of said fourth filter group selects predetermined wavelengths of light from said phase delayed second output of said second optical channel;
a third predeterminable relative phase delay between said first filter output and said second filter output;
an optical coupling between said relative phase delayed first filter output and said relative phase delayed second filter output, said optical coupling having a first output and a second output;
a third output of said plurality of outputs of said chip in common with said phase delayed second input of said second optical channel;
a fourth output of said plurality of outputs of said chip in common with said phase delayed second output of said second optical channel;
a fifth output of said plurality of outputs of said chip in common with said first output of said optical coupling;
a sixth output of said plurality of outputs of said chip in common with said second output of said optical coupling; and
an electronic control subsystem in operative communication with said chip for facilitating said predeterminable relative phase delays.
5. The quantum computation device of claim 1, wherein said tangentiality permits a coupling of light between said ring resonator and said optical channels at said first, said second, said third and said fourth points.
6. The quantum computation device of claim 4, wherein said first predeterminable relative phase delay is induced by a relative difference in length between said first optical channel and said second optical channel.
7. The quantum computation device of claim 4, wherein said second predeterminable relative phase delay is induced by a relative difference in the length of optical channel from said second input to said third output, and the length of optical channel from said second output to said fourth output.
8. The quantum computation device of claim 4, wherein said third predeterminable relative phase delay is induced by a relative difference in the length of optical channel from said first filter output to said optical coupling, and the length of optical channel from said second filter output to said optical coupling.
9. The quantum computation device of claim 6, wherein said relative difference in length is induced by thermal expansion further induced by a heated medium in proximity of said optical channels.
10. The quantum computation device of claim 7, wherein said relative difference in length is induced by thermal expansion further induced by a heated medium in proximity of said optical channels.
11. The quantum computation device of claim 8, wherein said relative difference in length is induced by thermal expansion further induced by a heated medium in proximity of said optical channels.
12. The quantum computation device of claim 4, where said first and said second filters are ring resonator filters.
13. The quantum computation device of claim 1, wherein each of said plurality of photon generators comprises a ring resonator on a chip of nonlinear optical material; said ring resonator having two connections of an optical waveguide or channel on each side of said ring resonator such that each said side forms an asymmetric length Mach-Zehnder interferometer to filter pump light from signal/idler photons created in said nonlinear optical material ring resonator; inside said ring resonator pump photons are critically coupled into said resonator to facilitate maximum generation of said signal/idler photons in said nonlinear optical material ring resonator and which remain in a cavity inside said ring resonator; said signal/idler photons generated in said nonlinear optical material based ring resonator by the process of either spontaneous parametric downconversion and spontaneous four wave mixing are over coupled to said resonator cavity to allow for maximum brightness of generated signal/idler photons exiting said nonlinear optical material-based ring resonator while said pump photons remain in said ring resonator cavity.
US16/280,144 2016-11-21 2019-02-20 Photon generator Abandoned US20190187380A1 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US16/280,144 US20190187380A1 (en) 2016-11-21 2019-02-20 Photon generator

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
US201662424739P 2016-11-21 2016-11-21
US15/833,274 US10466418B2 (en) 2016-11-21 2017-12-06 Photon generator
US16/280,144 US20190187380A1 (en) 2016-11-21 2019-02-20 Photon generator

Related Parent Applications (1)

Application Number Title Priority Date Filing Date
US15/833,274 Continuation US10466418B2 (en) 2016-11-21 2017-12-06 Photon generator

Publications (1)

Publication Number Publication Date
US20190187380A1 true US20190187380A1 (en) 2019-06-20

Family

ID=64271563

Family Applications (3)

Application Number Title Priority Date Filing Date
US15/813,442 Abandoned US20180335570A1 (en) 2016-11-21 2017-11-15 Photon generator
US15/833,274 Active US10466418B2 (en) 2016-11-21 2017-12-06 Photon generator
US16/280,144 Abandoned US20190187380A1 (en) 2016-11-21 2019-02-20 Photon generator

Family Applications Before (2)

Application Number Title Priority Date Filing Date
US15/813,442 Abandoned US20180335570A1 (en) 2016-11-21 2017-11-15 Photon generator
US15/833,274 Active US10466418B2 (en) 2016-11-21 2017-12-06 Photon generator

Country Status (1)

Country Link
US (3) US20180335570A1 (en)

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US10656336B1 (en) * 2018-11-08 2020-05-19 Luminous Computing, Inc. Method for phase-based photonic computing
US11016315B2 (en) * 2019-07-11 2021-05-25 Luminous Computing, Inc. Photonic bandgap phase modulator, optical filter bank, photonic computing system, and methods of use
US11269179B2 (en) 2018-04-30 2022-03-08 The Trustees Of Princeton University Photonic filter bank system and method of use
US20220326068A1 (en) * 2021-04-12 2022-10-13 Wuhan University Of Technology Grating enhanced distributed vibration demodulation system and method based on three-pulse shearing interference
US11500410B1 (en) * 2020-05-06 2022-11-15 Luminous Computing, Inc. System and method for parallel photonic computation

Families Citing this family (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US10809592B2 (en) * 2017-08-18 2020-10-20 Xanadu Quantum Technologies Inc. Methods and apparatus for producing highly tunable squeezed light
US10372014B1 (en) * 2018-11-15 2019-08-06 Psiquantum, Corp. Coupled resonator photon-pair sources
CN110333637B (en) * 2019-06-18 2022-07-19 中国人民解放军国防科技大学 Adjustable nonlinear frequency conversion waveguide chip based on Mach-Zehnder interferometer-micro-ring coupling
US11079542B2 (en) * 2019-10-21 2021-08-03 Honeywell International Inc. Integrated photonics source and detector of entangled photons
US11199661B2 (en) 2019-10-21 2021-12-14 Honeywell International Inc. Integrated photonics vertical coupler
US11320720B2 (en) 2019-10-21 2022-05-03 Honeywell International Inc. Integrated photonics mode splitter and converter
SE545304C2 (en) * 2021-07-08 2023-06-27 Oskar Bjarki Helgason An optical resonator frequency comb
CN117908310B (en) * 2024-03-20 2024-05-28 华中科技大学 Quantum light source system capable of self-suppressing pumping

Family Cites Families (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US8655114B2 (en) * 2007-03-26 2014-02-18 Massachusetts Institute Of Technology Hitless tuning and switching of optical resonator amplitude and phase responses
US8019185B2 (en) * 2008-02-14 2011-09-13 Hrl Laboratories, Llc Unit-cell array optical signal processor
US7941014B1 (en) * 2008-04-09 2011-05-10 Sandia Corporation Optical waveguide device with an adiabatically-varying width
US8483521B2 (en) * 2009-05-29 2013-07-09 Massachusetts Institute Of Technology Cavity dynamics compensation in resonant optical modulators
US9778493B1 (en) * 2016-09-22 2017-10-03 Oracle International Corporation Dual-ring-modulated laser that uses push-push/pull-pull modulation

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US11269179B2 (en) 2018-04-30 2022-03-08 The Trustees Of Princeton University Photonic filter bank system and method of use
US10656336B1 (en) * 2018-11-08 2020-05-19 Luminous Computing, Inc. Method for phase-based photonic computing
US11442228B2 (en) 2018-11-08 2022-09-13 Luminous Computing, Inc. System for phase-based photonic computing
US12032210B2 (en) 2018-11-08 2024-07-09 Luminous Computing, Inc. Method of optical modulation for photonic computing
US11016315B2 (en) * 2019-07-11 2021-05-25 Luminous Computing, Inc. Photonic bandgap phase modulator, optical filter bank, photonic computing system, and methods of use
US11656485B2 (en) 2019-07-11 2023-05-23 Luminous Computing, Inc. Photonic bandgap phase modulator, optical filter bank, photonic computing system, and methods of use
US12085790B2 (en) 2019-07-11 2024-09-10 Luminous Computing, Inc. Photonic bandgap phase modulator, optical filter bank, photonic computing system, and methods of use
US11500410B1 (en) * 2020-05-06 2022-11-15 Luminous Computing, Inc. System and method for parallel photonic computation
US20220326068A1 (en) * 2021-04-12 2022-10-13 Wuhan University Of Technology Grating enhanced distributed vibration demodulation system and method based on three-pulse shearing interference
US12055433B2 (en) * 2021-04-12 2024-08-06 Wuhan University Of Technology Grating enhanced distributed vibration demodulation system and method based on three-pulse shearing interference

Also Published As

Publication number Publication date
US20190146155A1 (en) 2019-05-16
US20180335570A1 (en) 2018-11-22
US10466418B2 (en) 2019-11-05

Similar Documents

Publication Publication Date Title
US10466418B2 (en) Photon generator
Arianfard et al. Three waveguide coupled sagnac loop reflectors for advanced spectral engineering
Liu et al. Integrated microwave photonic filters
Surendar et al. A novel proposal for all-optical 1-bit comparator using nonlinear PhCRRs
Manolatou et al. Coupling of modes analysis of resonant channel add-drop filters
Krapick et al. An efficient integrated two-color source for heralded single photons
Serajmohammadi et al. All optical NAND gate based on nonlinear photonic crystal ring resonator
CN107870397B (en) Wavelength selective optical switch
Yi et al. Multi-functional photonic processors using coherent network of micro-ring resonators
Zhou et al. Waveguide self-coupling based reconfigurable resonance structure for optical filtering and delay
Qiu et al. Silicon add-drop filter based on multimode grating assisted couplers
Sridarshini et al. Compact 3× 3 wavelength routing for photonic integrated circuits
Afifi et al. Contra-directional couplers as pump rejection and recycling filters for on-chip photon-pair sources
Haldar et al. Theory and design of off-axis microring resonators for high-density on-chip photonic applications
Lin et al. 1× 4 optical multiplexer based on the self-collimation effect of 2D photonic crystal
Lu et al. Wavelength routers with low crosstalk using photonic crystal point defect micro-cavities
Sridarshini et al. Ultra-compact all-optical logical circuits for photonic integrated circuits
Serajmohammadi All-optical NAND gate based on nonlinear photonic crystal ring resonators
Yu et al. Tunable optical delay line for optical time-division multiplexer
Zhuang et al. Single-chip optical beam forming network in LPCVD waveguide technology based on optical ring resonators
Zhang et al. Optical spectral shaping based on reconfigurable integrated microring resonator-coupled Fabry–Perot cavity
Dingel Multifunctional optical filter using direct-coupled and cross-coupled all-pass filters
Soref et al. Tunable optical-microwave filters optimized for 100 MHz resolution
US10288811B1 (en) Optical switching between waveguides by adjacent resonant structure coupling
Luo et al. Polymeric N-stage serial-cascaded four-port optical router with scalable 3 N channel wavelengths for wideband signal routing application

Legal Events

Date Code Title Description
STPP Information on status: patent application and granting procedure in general

Free format text: NOTICE OF ALLOWANCE MAILED -- APPLICATION RECEIVED IN OFFICE OF PUBLICATIONS

STCB Information on status: application discontinuation

Free format text: ABANDONED -- FAILURE TO PAY ISSUE FEE