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    • 1. 发明授权
    • Phase locking in a multi-channel quantum communication system
    • 多通道量子通信系统中的锁相
    • US07706536B2
    • 2010-04-27
    • US11210941
    • 2005-08-24
    • Mihaela DinuChristophe J. DorrerClinton Randy GilesInuk KangDan Mark Marom
    • Mihaela DinuChristophe J. DorrerClinton Randy GilesInuk KangDan Mark Marom
    • H04K1/00
    • H04L9/0858
    • A communication system adapted to use wavelength (frequency) division multiplexing for quantum-key distribution (QKD) and having a transmitter coupled to a receiver via a transmission link. In one embodiment, the receiver is adapted to (i) phase-shift a local oscillator (LO) signal generated at the receiver, (ii) combine the LO signal with a quantum-information (QI) signal received via the transmission link from the transmitter to produce interference signals, (iii) measure an intensity difference for these interference signals, and (iv) phase-lock the LO signal to the QI signal based on the measurement result. In one configuration, the QI signal has a plurality of pilot frequency components, each carrying a training signal, and a plurality of QKD frequency components, each carrying quantum key data. Advantageously, the system can maintain a phase lock for the QKD frequency components of the QI and LO signals, while the QKD frequency components of the QI signal continuously carry quantum key data.
    • 一种适于使用用于量子密钥分配(QKD)的波长(频率)分割复用并且具有通过传输链路耦合到接收机的发射机的通信系统。 在一个实施例中,接收机适于(i)移位在接收机处产生的本地振荡器(LO)信号,(ii)将LO信号与经由传输链路从该接收机接收的量子信息(QI)信号组合 发射机产生干扰信号,(iii)测量这些干扰信号的强度差,以及(iv)基于测量结果将LO信号锁相到QI信号。 在一个配置中,QI信号具有多个导频频率分量,每个导频频率分量携带训练信号,以及多个QKD频率分量,每个携带量子密钥数据。 有利的是,该系统可以维持QI和LO信号的QKD频率分量的相位锁定,而QI信号的QKD频率分量连续携带量子密钥数据。
    • 2. 发明授权
    • Optical pulse shaper having hybrid planar lightwave circuit and free-space optics with MEMS piston-motion micromirrors and feedback control
    • 具有混合平面光波电路和具有MEMS活塞微反射镜和反馈控制的自由空间光学器件的光脉冲整形器
    • US07289697B2
    • 2007-10-30
    • US11236291
    • 2005-09-27
    • Christophe J. DorrerDan Mark Marom
    • Christophe J. DorrerDan Mark Marom
    • G02B6/32G02B6/43
    • G02B6/12019G02B6/3512
    • An optical pulse shaper without polarization dependencies includes, a planar lightwave circuit (PLC) having an arrayed waveguide and free space optics, combined with a lens and micromirror array characterized by piston-motion. The micromirror array is coupled to a controller that provides signals to the array for adjusting the positions of the micromirrors, which are used as a spatial light modulator to provide at least phase modulation to one or more of the separated frequency components of an input optical signal. The frequency separated components, including modified components, are recombined and directed back to the PLC to form a synthesized optical pulse. Information regarding the characteristics of the synthesized optical pulse is extracted from a spectrogram of that pulse. Extracted information is provided to the controller and responsive thereto the controller may generate signals for adjusting the position of one or more micromirrors.
    • 没有偏振相关性的光学脉冲整形器包括具有阵列波导和自由空间光学器件的平面光波电路(PLC),其结合具有活塞运动特征的透镜和微镜阵列。 微镜阵列耦合到控制器,该控制器向阵列提供信号,用于调整微镜的位置,微反射镜的位置用作空间光调制器以向输入光信号的一个或多个分离的频率分量提供至少相位调制 。 频率分离的组件,包括修改的组件,被重新组合并引导回PLC,以形成合成的光脉冲。 从该脉冲的光谱图中提取关于合成光脉冲的特性的信息。 提取的信息被提供给控制器并且响应于此,控制器可以生成用于调整一个或多个微镜的位置的信号。
    • 6. 发明授权
    • Coherent optical signal processing
    • 相干光信号处理
    • US08204378B1
    • 2012-06-19
    • US12409030
    • 2009-03-23
    • Robert A. Marsland, Jr.Christophe J. Dorrer
    • Robert A. Marsland, Jr.Christophe J. Dorrer
    • H04J14/06H04B10/06H04B10/00
    • G01S3/783H04B10/613H04B10/614
    • Coherent optical signal processing is performed in a coherent receiver (or diagnostic/testing apparatus) that converts an amplitude and/or angle-modulated optical signal into two electrical signals. A simple receiver can only detect one phase of the signal and only the polarization that is aligned with a local oscillator laser polarization. To detect both phases and both polarizations, two sets of two interferometers, one each with a π/2 phase shift are required. Coherent optical signal processing methods, apparatus, techniques, etc. are disclosed that include individual components comprising a polarization combiner, a Savart device and photodetection apparatus with substantially reduced temperature and alignment sensitivity operating in optical communication systems and/or subsystems. The various embodiments can be used alone or in such combinations to provide improved coherent optical signal processing in a receiver.
    • 相干光信号处理在将幅度和/或角度调制的光信号转换成两个电信号的相干接收机(或诊断/测试装置)中执行。 简单的接收机只能检测信号的一个相位,只能检测与本机振荡器激光偏振对准的极化。 为了检测两相和两个极化,需要两组两个干涉仪,每个具有&pgr / / 2相移。 公开了相干光信号处理方法,装置,技术等,其包括具有在光通信系统和/或子系统中操作的具有显着降低的温度和对准灵敏度的偏振组合器,Savart装置和光电检测装置的各个部件。 各种实施例可以单独使用或以这种组合使用以在接收器中提供改进的相干光信号处理。
    • 7. 发明授权
    • Method and apparatus for characterization of the response of optical devices
    • 用于表征光学器件响应的方法和装置
    • US07609385B2
    • 2009-10-27
    • US11206622
    • 2005-08-18
    • Christophe J. Dorrer
    • Christophe J. Dorrer
    • G01B9/02
    • G01M11/00
    • Techniques for characterizing the response of an optical device comprising modulating at least one signal using the device; coupling the modulated signal with a reference signal in a variety of ways; detecting the coupled signals; and obtaining the response of the modulator by analyzing the detected signals, are described. In a heterodyne embodiment, the method includes modulating a first optical signal using the optical device to produce a modulated first optical signal, the modulated first optical signal is combined with a second optical signal in a different spectral region; and the response of the optical device is determined from the intensity of the combined optical signal. A homodyne method using various splitting and recombining of the modulated optical signal with a reference signal is also described.
    • 用于表征光学装置的响应的技术,包括使用所述装置调制至少一个信号; 以多种方式将调制信号与参考信号耦合; 检测耦合信号; 并且通过分析检测到的信号来获得调制器的响应。 在外差实施例中,该方法包括使用该光学装置调制第一光信号以产生经调制的第一光信号,将调制的第一光信号与不同光谱区中的第二光信号组合; 并且根据组合的光信号的强度确定光学装置的响应。 还描述了使用调制光信号与参考信号的各种分离和重组的零差方法。
    • 8. 发明授权
    • Apparatus for modulating one or both of spectral phase and amplitude of an optical signal
    • 用于调制光信号的光谱相位和幅度中的一个或两个的装置
    • US07321454B2
    • 2008-01-22
    • US11245760
    • 2005-10-07
    • Christophe J. DorrerDan M. Marom
    • Christophe J. DorrerDan M. Marom
    • G02B26/00
    • H04B10/505G02B26/0833H04B10/5053
    • The invention includes a method and apparatus for modulating one or both of spectral phase and amplitude of a received optical signal. The apparatus includes a spatial dispersion mechanism for spatially dispersing the received optical signal to enable optical communication of the received optical signal to an array of modulators. The apparatus includes a modulating mechanism having a first modulating component and a second modulating component. A first portion of the spatially dispersed optical signal is incident on the first modulating component and a second portion of the spatially dispersed optical signal is incident on the second modulating portion. The apparatus further includes a controller coupled to the modulating mechanism. The controller is adapted for moving the first and second modulating components in a direction normal to their planes for modulating one or both of phase and amplitude of the received optical signal.
    • 本发明包括一种用于调制所接收的光信号的频谱相位和幅度之一或两者的方法和装置。 该装置包括空间分散机构,用于空间分散接收的光信号,以使所接收的光信号能够与调制器的阵列进行光通信。 该装置包括具有第一调制部件和第二调制部件的调制机构。 空间分散的光信号的第一部分入射到第一调制分量上,空间分散的光信号的第二部分入射到第二调制部分上。 该装置还包括耦合到调制机构的控制器。 控制器适于沿着与其平面垂直的方向移动第一和第二调制分量,用于调制所接收的光信号的相位和幅度之一或两者。
    • 9. 发明授权
    • Method and apparatus for characterizing the electric field of periodic and non-periodic optical signals
    • 用于表征周期性和非周期性光信号的电场的方法和装置
    • US07298489B2
    • 2007-11-20
    • US11129244
    • 2005-05-13
    • Christophe J. Dorrer
    • Christophe J. Dorrer
    • G01B9/02
    • G01J11/00
    • An interferometric technique measures the time-dependent electric field of a periodic or a non-periodic (data-encoded) optical signal under test using samples of its interference with a reference source of short optical pulses. The reference signal is a sequence of optical pulses at a repetition rate different from that of the signal under test. The difference in repetition rates of the two signals performs a scanning of the relative delay between the two signals, i.e. each pulse from the reference signal will overlap with the signal under test at a different time. The real and imaginary part of each of the plurality of interference between the two signals are then measured to determine samples of the electric field of the optical signal under test at each of those times. When needed, various types of averaging are performed on the samples of the electric field. If the signal under test is a data-encoded source, averaging is performed on groups of samples corresponding to the same symbol state of the data-encoded source.
    • 干涉技术使用其与短光脉冲的参考源的干涉的样本来测量正在测试的周期性或非周期性(数据编码的)光信号的时间依赖性电场。 参考信号是与被测信号不同的重复频率的一系列光脉冲。 两个信号的重复率的差异执行两个信号之间的相对延迟的扫描,即,来自参考信号的每个脉冲将在不同的时间与被测信号重叠。 然后测量两个信号之间的多个干扰中的每一个的实部和虚部,以确定在每个时刻的每个被测光信号的电场的采样。 当需要时,对电场的样本进行各种平均化。 如果被测信号是数据编码源,则对与数据编码源的相同符号状态相对应的采样组执行平均。