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    • 62. 发明授权
    • Magnetically-packaged optical MEMs device
    • 磁性封装的光学MEM器件
    • US06574026B2
    • 2003-06-03
    • US09731493
    • 2000-12-07
    • Sungho JinHyongsok Soh
    • Sungho JinHyongsok Soh
    • G02B2608
    • B81B7/0067B81B2201/047B81C2203/058G02B26/0841Y10S359/904
    • In accordance with the invention, the component layer, the spacer and the actuator layer of a MEMs device are assembled at ambient temperature and held together in lateral alignment by upper and lower magnets. Such ambient temperature magnetic packaging greatly minimizes the undesirable exposure of the sensitive MEMs components to high temperatures. The resulting MEMs device exhibits the high dimensional accuracy and stability. In a preferred embodiment, the component layer comprises a layer of movable mirrors and a spacer aerodynamically and electrostatically isolates each mirror, minimizing cross-talk between adjacent mirrors.
    • 根据本发明,MEMs器件的元件层,间隔物和致动器层在环境温度下组装并通过上部和下部磁体横向对准地保持在一起。 这种环境温度磁性包装极大地最大限度地减少敏感MEM组分对高温的不良暴露。 所得到的MEMs器件具有高尺寸精度和稳定性。 在优选实施例中,组件层包括可移动反射镜层和间隔空间动力学和静电隔离每个反射镜,使相邻反射镜之间的串扰最小化。
    • 63. 发明授权
    • Field emitting device comprising field-concentrating nanoconductor assembly and method for making the same
    • 场致发射器件包括场集中纳米电导体组件及其制造方法
    • US06538367B1
    • 2003-03-25
    • US09369802
    • 1999-08-06
    • Kyung Moon ChoiSungho JinGregory Peter KochanskiWei Zhu
    • Kyung Moon ChoiSungho JinGregory Peter KochanskiWei Zhu
    • H01J102
    • H01J1/304B82Y10/00H01J9/025H01J23/04H01J2201/30469H01J2225/38Y10S977/939
    • This invention is predicated on applicants' discovery that a highly oriented nanoconductor structure alone does not guarantee efficient field emission. To the contrary, the conventional densely populated, highly oriented structures actually yield relatively poor field emission characteristics. Applicants have determined that the individual nanoconductors in conventional assemblies are so closely spaced that they shield each other from effective field concentration at the ends, thus diminishing the driving force for efficient electron emission. In accordance with the invention, an improved field emitting nanoconductors assembly (a “low density nanoconductor assembly”) comprises an array of nanoconductors which are highly aligned but spaced from each other no closer than 10% of the height of the nanoconductors. In this way, the field strength at the ends will be at least 50% of the maximal field concentration possible. Several ways of making the optimally low density assemblies are described along with several devices employing the assemblies.
    • 本发明基于申请人的发现,即单独的高度取向的纳米结构结构不能保证有效的场发射。 相反,传统的人口稠密,高度取向的结构实际上产生相对较差的场致发射特性。 申请人已经确定,常规组件中的单个纳米电感器如此紧密地间隔开,使得它们彼此屏蔽在端部处的有效场浓度,从而减少了有效电子发射的驱动力。根据本发明,改进的场发射纳米结构器件组件 “低密度纳米导体组件”)包括高度对准但彼此间隔不超过纳米电感器高度的10%的纳米电感器阵列。 以这种方式,末端的场强将是可能的最大场浓度的至少50%。 使用几种使用组件的装置来描述制造最佳低密度组件的几种方式。
    • 64. 发明授权
    • Article comprising small diameter nanowires and method for making the same
    • 文章包括小直径纳米线及其制造方法
    • US06465132B1
    • 2002-10-15
    • US09483297
    • 2000-01-14
    • Sungho Jin
    • Sungho Jin
    • H01M458
    • C01B3/0084B82Y10/00C01B3/0031H01J1/3044H01J2201/30469H01M4/13H01M4/133H01M4/134H01M4/139H01M4/1393H01M4/1395H01M4/242H01M4/38H01M4/66H01M4/661H01M4/663H01M4/664H01M4/70H01M2004/021Y02E60/327Y10S977/762Y10S977/948
    • A nanowire structure that may be used to fabricate small diameter and aligned nanowires, e.g., having a diameter of less than 50 nm and more preferably, less than 10 nm, is disclosed. The structure includes an alloy substrate having at least a first phase and a second phase, wherein the first phase is catalytic and the second phase is less catalytic (weakly or non-catalytic). A plurality of small diameter nanowires are grown from the first phase of the alloy substrate. Each one of the plurality of nanowires is substantially vertically aligned relative to the substrate and preferably, the average deviation from full vertical alignment is less than 25 degrees, and more preferably less than 15 degrees. The alloy substrate is fabricated with an alloy system of catalytic and non (or less) catalytic elements that are phase separated, e.g., by spinodal decomposition or nucleation-and-growth type transformation. Also disclosed is a method for making small diameter nanowires comprising providing the phase-separated substrate including catalytic regions, elongating the substrate to reduce the diameters of the catalytic regions, and then growing the plurality of nanowires from the reduced-diameter catalytic regions. The small diameter nanowires may be used for many applications, including microwave amplifier devices, field emission display devices, and lithium-rechargeable batteries.
    • 公开了可用于制造小直径和对准的纳米线的纳米线结构,例如具有小于50nm,更优选小于10nm的直径。 该结构包括具有至少第一相和第二相的合金基底,其中第一相为催化剂,第二相较少催化(弱或非催化)。 从合金基板的第一相生长多根小直径的纳米线。 多个纳米线中的每一个相对于基底基本上垂直对齐,并且优选地,与全垂直对准的平均偏差小于25度,更优选小于15度。 合金基底由催化和非(或更少)催化元素的合金体系制成,其相分离,例如通过旋节分解或成核 - 生长型转化。 还公开了一种制造小直径纳米线的方法,包括提供包括催化区域的相分离基材,延长基材以减小催化区域的直径,然后从直径减小的催化区域生长多个纳米线。 小直径纳米线可用于许多应用,包括微波放大器装置,场致发射显示装置和锂可充电电池。
    • 65. 发明授权
    • Magnetically tunable optical attenuator and method of attenuating signals
    • 磁调谐光衰减器和衰减信号的方法
    • US06301425B1
    • 2001-10-09
    • US09255299
    • 1999-02-22
    • Rolando Patricio EspindolaRandy Clinton GilesSungho JinHareesh Mavoori
    • Rolando Patricio EspindolaRandy Clinton GilesSungho JinHareesh Mavoori
    • G02B600
    • G02B6/353G02B6/266G02B6/3532G02B6/3572G02B6/358G02B6/3594
    • A variable attenuator device is disclosed that may be magnetically and latchably controlled such that it does not require a continuous power supply to maintain a particular loss level. The variable attenuator comprises two optical components disposed in spaced apart relation to define a gap between them and a magnetic shutter positioned within the gap. The shutter is movable, due to its magnetic properties, from a first position to at least a second position, where the second position may be within, partially within, or outside of the gap. A mechanism is provided for magnetizing or actuating the shutter to cause it to move from the first position to the at least second position. When the shutter is in the first position, it causes a certain amount of attenuation in the signal being transmitted between the two optical components, and when it moves to the at least second position, a different amount of attenuation is caused, such that movement of the shutter causes a variation in the attenuation. With this attenuator, the variation in attenuation may be achieved via coupling loss while the optical components (e.g., mating fibers), are maintained in a fixed position, thereby avoiding difficulties associated with fiber movement.
    • 公开了一种可变的衰减器装置,其可被磁性和可锁定地控制,使得其不需要连续的电源来维持特定的损耗水平。 可变衰减器包括以间隔开的关系设置的两个光学部件,以限定它们之间的间隙和位于间隙内的磁性快门。 快门由于其磁性,可以从第一位置移动到至少第二位置,其中第二位置可以在间隙的内部,部分地在外部或外部。 提供了用于磁化或致动快门以使其从第一位置移动到至少第二位置的机构。 当快门处于第一位置时,其在两个光学部件之间的信号中产生一定量的衰减,并且当其移动到至少第二位置时,引起不同的衰减量, 快门会导致衰减的变化。 利用该衰减器,可以通过耦合损耗来实现衰减的变化,同时光学部件(例如,配合光纤)保持在固定位置,从而避免与光纤移动有关的困难。
    • 66. 发明授权
    • Tactile sensor comprising nanowires and method for making the same
    • 包含纳米线的触觉传感器及其制造方法
    • US06286226B1
    • 2001-09-11
    • US09405641
    • 1999-09-24
    • Sungho Jin
    • Sungho Jin
    • G01B2100
    • H01H1/06H01H1/0094Y10S977/956
    • A tactile sensor device is disclosed that can be used for high resolution tactile sensing. The sensor may be used as a tactile shear sensor. It comprises a circuit substrate; an array of contact pads on the circuit substrate, and a set of nanowires attached to each of the contact pads. The contact pads may be isolated or formed from a matrix of interconnecting strips of material. Each set of nanowires comprises at least one and preferably a plurality of nanowires that are desirably vertically aligned and equal in length. When an object contacts at least one of the plurality of sets of nanowires, it causes at least one set of nanowires to bend and make contact along a portion of the length thereof with at least another set of nanowires. The position and movement activity of the object can be sensed by electrically interrogating pairs of contact pads to determine whether a connection has been made between them.
    • 公开了可用于高分辨率触觉感测的触觉传感器装置。 传感器可以用作触觉剪切传感器。 它包括电路基板; 电路基板上的接触焊盘的阵列,以及连接到每个接触焊盘的一组纳米线。 接触垫可以由相互连接的材料条的基体隔离或形成。 每组纳米线包括至少一个并且优选多个纳米线,其希望垂直对准并且长度相等。 当物体接触多组纳米线中的至少一个时,它使至少一组纳米线弯曲并且沿其长度的一部分与至少另一组纳米线接触。 物体的位置和运动活动可以通过电询问的接触垫对来检测,以确定它们之间是否已经形成连接。
    • 68. 发明授权
    • Magnetically tunable and latchable broad-range semiconductor laser
    • 可调谐和可锁定的宽范围半导体激光器
    • US06154471A
    • 2000-11-28
    • US255582
    • 1999-02-22
    • Sungho JinHareesh Mavoori
    • Sungho JinHareesh Mavoori
    • H01S5/183H01S5/02H01S5/14H04J14/02H01S3/10
    • H04J14/0227H01S5/18366H04J14/0278
    • The invention provides a device with an improved tunable laser structure, the structure useful with surface emitting lasers and capable of exhibiting desirable latchability. The tunable laser of the invention contains a laser structure having a lower reflector, an active laser region, and an upper reflector. The upper reflector contains a non-moveable reflector portion located adjacent the active laser region and a moveable reflector portion located a spaced distance from the non-moveable reflector portion. A magnetic material is located either on a surface of the moveable reflector portion or on a surface in contact with the moveable reflector portion, and a programmable magnet is located near the magnetic material, the magnet capable of inducing controlled movement of the magnetic material. This movement in turn induces movement of the moveable reflector portion such that the spaced distance between the moveable reflector portion and the non-moveable reflector portion is capable of being adjusted. By adjusting this spaced distance (i.e., the air gap between the moveable and non-moveable reflector portions), the phase of reflection and thus the laser output wavelength is controlled.
    • 本发明提供一种具有改进的可调谐激光器结构的器件,该结构可用于表面发射激光器并且能够表现出期望的可锁定性。 本发明的可调激光器包括具有下反射器,有源激光器区域和上反射器的激光器结构。 上反射器包含位于有源激光区域附近的不可移动的反射器部分和与不可移动反射器部分间隔开的位置的可移动反射器部分。 磁性材料位于可移动反射器部分的表面上或与可移动反射器部分接触的表面上,并且可编程磁体位于磁性材料附近,该磁体能够引起磁性材料的受控移动。 这种移动又引起可移动反射器部分的移动,使得能够调节可移动反射器部分和不可移动反射器部分之间的间隔距离。 通过调节该间隔距离(即,可移动和不可移动的反射器部分之间的空气间隙),控制反射相位,从而控制激光输出波长。
    • 69. 发明授权
    • Passively temperature-compensated wavelength-tunable device comprising
flexed optical gratings and communication systems using such devices
    • 被动温度补偿波长可调谐装置包括弯曲光栅和使用这种装置的通信系统
    • US6148128A
    • 2000-11-14
    • US162324
    • 1998-09-28
    • Sungho JinHareesh Mavoori
    • Sungho JinHareesh Mavoori
    • G02B6/34G02F1/01H01S3/067H01S3/1055H01S5/14
    • G02B6/022G02B6/0218G02B6/29322G02B6/2938G02B6/29398G02F1/011G02F2201/307H01S3/0675H01S3/1055H01S5/146
    • In accordance with the invention, a passively temperature-compensated tunable optical grating device comprises a grating, which is fixed at both ends to a support frame, and is mechanically or magnetically flexed so that a tensile strain induced in the grating reconfigures the resonant wavelength of the grating. Preferred embodiments include at least one waveguide grating, a flexing mechanism capable of inducing a latchable change in grating periodicity and at least one negative thermal expansion component which, upon heating, reduces the strain in the grating so that the temperature-induced wavelength shift is substantially cancelled out. The device can reduce the temperature-dependent wavelength change to less than 0.5 nm/100 deg. C, and preferably less than 0.05 nm/100 deg. C. In a preferred embodiment, the packaging assembly also includes a fine-wavelength adjusting mechanism for post-assembly corrective tuning. The device is especially useful in WDM communication systems, particularly for adding or dropping channels, for dynamically gain-equalizing optical amplifiers, for tunable lasers, and for dispersion compensation.
    • 根据本发明,被动温度补偿的可调光学光栅装置包括光栅,其被固定在两端到支撑框架上,并被机械或磁力弯曲,使得在光栅中感应的拉伸应变重新配置了 光栅。 优选实施例包括至少一个波导光栅,能够引起光栅周期性的可闩锁变化的弯曲机构和至少一个负热膨胀部件,其在加热时减小光栅中的应变,使得温度感应波长移位基本上 取消了 该器件可以将依赖于温度的波长变化降低到小于0.5nm / 100deg。 优选小于0.05nm / 100度。 在优选实施例中,包装组件还包括用于后组装校正调谐的精细波长调节机构。 该器件在WDM通信系统中特别有用,特别是用于增加或删除通道,用于动态增益均衡的光放大器,可调谐激光器和色散补偿。
    • 70. 发明授权
    • Temperature-compensated optical fiber gratings with fine wavelength
tuning
    • 具有精细波长调谐的温度补偿光纤光栅
    • US6101301A
    • 2000-08-08
    • US62339
    • 1998-04-17
    • Jon W. EngelberthRolando Patricio EspindolaSungho JinPaul Joseph LemaireHareesh Mavoori
    • Jon W. EngelberthRolando Patricio EspindolaSungho JinPaul Joseph LemaireHareesh Mavoori
    • G02B6/34
    • G02B6/022G02B6/0218
    • A temperature compensated optical fiber grating device comprises a longitudinally extending optical fiber grating having a length and a packaging assembly for the grating comprising a first longitudinally extending body of material having a first coefficient of thermal expansion (CTE) and second and third longitudinally extending bodies of material having CTE's lower than the first CTE. The three bodies are mechanically attached at alternate ends to form a composite structure having an effective negative CTE between two ends to which the grating is attached. The resulting grating device can be made in compact form having an overall length less than 30% more than the grating (and preferably less than 10%) and can reduce the temperature dependent wavelength change in the grating to less than 0.2 nm/100.degree. C. and preferably less than 0.05 nm/100.degree. C. In a preferred embodiment, the packaging bodies include a cylinder enclosing the grating.
    • 温度补偿光纤光栅装置包括具有长度的纵向延伸的光纤光栅和用于光栅的包装组件,其包括具有第一热膨胀系数(CTE)的第一纵向延伸的材料体,以及第二和第三纵向延伸体 CTE低于第一个CTE的材料。 这三个机构在交替的端部机械地连接以形成复合结构,该复合结构在光栅所连接的两端之间具有有效的负CTE。 所得到的光栅装置可以制成紧凑形式,其整体长度小于光栅的30%(优选小于10%),并且可以将光栅中的温度相关波长变化降低到小于0.2nm / 100℃ ,优选小于0.05nm / 100℃。在优选实施例中,包装体包括封闭光栅的圆柱体。