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    • 1. 发明授权
    • Optofluidic microscope device with photosensor array
    • 具有光电传感器阵列的光电显微镜装置
    • US08314933B2
    • 2012-11-20
    • US12398050
    • 2009-03-04
    • Xiquan CuiXin HengLap Man LeeChanghuei Yang
    • Xiquan CuiXin HengLap Man LeeChanghuei Yang
    • G01N21/00
    • G01N21/53G01N21/6458
    • Embodiments of the present invention relate to techniques for improving optofluidic microscope (OFM) devices. One technique which may be used eliminates the aperture layer covering the light detector layer. Other techniques retain the aperture layer, reversing the relative position of the light source and light detector such that light passes through the aperture layer before passing through the fluid channel to the light detector. Another technique adds an optical tweezer for controlling the movement of objects moving through the fluid channel. Another technique adds an optical fiber bundle to relay light from light transmissive regions to a remote light detector. Another technique adds two electrodes at ends of the fluid channel to generate an electrical field capable of moving objects through the fluid channel while suppressing rotation. These techniques can be employed separately or in combination to improve the capabilities of OFM devices.
    • 本发明的实施例涉及用于改进光流体显微镜(OFM)装置的技术。 可以使用的一种技术消除了覆盖光检测器层的孔径层。 其他技术保留孔径层,反转光源和光检测器的相对位置,使得光在通过流体通道之前通过孔层,到达光检测器。 另一种技术增加了用于控制移动通过流体通道的物体运动的光学镊子。 另一种技术增加了光纤束,以将来自光透射区域的光中继到远程光检测器。 另一种技术在流体通道的端部添加两个电极,以产生能够通过流体通道移动物体同时抑制旋转的电场。 这些技术可以单独使用或组合使用以提高OFM设备的能力。
    • 2. 发明申请
    • OPTOFLUIDIC MICROSCOPE DEVICE WITH PHOTOSENSOR ARRAY
    • 带有光电传感器阵列的光学显微镜装置
    • US20110181884A1
    • 2011-07-28
    • US12398050
    • 2009-03-04
    • Xiquan CuiXin HengLap Man LeeChanghuei Yang
    • Xiquan CuiXin HengLap Man LeeChanghuei Yang
    • G01N21/59
    • G01N21/53G01N21/6458
    • Embodiments of the present invention relate to techniques for improving optofluidic microscope (OFM) devices. One technique which may be used eliminates the aperture layer covering the light detector layer. Other techniques retain the aperture layer, reversing the relative position of the light source and light detector such that light passes through the aperture layer before passing through the fluid channel to the light detector. Another technique adds an optical tweezer for controlling the movement of objects moving through the fluid channel. Another technique adds an optical fiber bundle to relay light from light transmissive regions to a remote light detector. Another technique adds two electrodes at ends of the fluid channel to generate an electrical field capable of moving objects through the fluid channel while suppressing rotation. These techniques can be employed separately or in combination to improve the capabilities of OFM devices.
    • 本发明的实施例涉及用于改进光流体显微镜(OFM)装置的技术。 可以使用的一种技术消除了覆盖光检测器层的孔径层。 其他技术保留孔径层,反转光源和光检测器的相对位置,使得光在通过流体通道之前通过孔层,到达光检测器。 另一种技术增加了用于控制移动通过流体通道的物体运动的光学镊子。 另一种技术增加了光纤束,以将来自光透射区域的光中继到远程光检测器。 另一种技术在流体通道的端部添加两个电极,以产生能够通过流体通道移动物体同时抑制旋转的电场。 这些技术可以单独使用或组合使用以提高OFM设备的能力。
    • 3. 发明申请
    • Techniques for Improving Optofluidic Microscope Devices
    • 改进光电显微镜装置的技术
    • US20110170105A1
    • 2011-07-14
    • US12638518
    • 2009-12-15
    • Xiquan CuiLap Man LeeChanghuei Yang
    • Xiquan CuiLap Man LeeChanghuei Yang
    • G01N21/05G01N21/85
    • G02B21/33
    • Embodiments of the present invention relate to techniques for improving optofluidic microscope (OFM) devices. One technique that may be used employs surface tension at a hydrophobic surface to passively pump the fluid sample through the fluid channel. Another technique uses electrodes to adjust the position of objects in the fluid channel. Another technique computationally adjusts the focal plane of an image wavefront measured using differential interference contrast (DIC) based on Young's interference by back propagating the image wavefront from the detection focal plane to a different focal plane. These techniques can be employed separately or in combination to improve the capabilities of OFM devices.
    • 本发明的实施例涉及用于改进光流体显微镜(OFM)装置的技术。 可以使用的一种技术使用在疏水表面处的表面张力来动态地将流体样品泵送通过流体通道。 另一种技术使用电极来调节物体在流体通道中的位置。 另一种技术通过从检测焦平面反向传播图像波前到不同焦平面,基于杨氏干扰,使用差分干涉对比度(DIC)来计算地调整图像波前的焦平面。 这些技术可以单独使用或组合使用以提高OFM设备的能力。
    • 4. 发明授权
    • Focal plane adjustment by back propagation in optofluidic microscope devices
    • 通过光电显微镜装置中的反向传播进行焦平面调整
    • US08325349B2
    • 2012-12-04
    • US12638518
    • 2009-12-15
    • Xiquan CuiLap Man LeeChanghuei Yang
    • Xiquan CuiLap Man LeeChanghuei Yang
    • G01N9/02
    • G02B21/33
    • Embodiments of the present invention relate to techniques for improving optofluidic microscope (OFM) devices. One technique that may be used employs surface tension at a hydrophobic surface to passively pump the fluid sample through the fluid channel. Another technique uses electrodes to adjust the position of objects in the fluid channel. Another technique computationally adjusts the focal plane of an image wavefront measured using differential interference contrast (DIC) based on Young's interference by back propagating the image wavefront from the detection focal plane to a different focal plane. These techniques can be employed separately or in combination to improve the capabilities of OFM devices.
    • 本发明的实施例涉及用于改进光流体显微镜(OFM)装置的技术。 可以使用的一种技术使用在疏水表面处的表面张力来动态地将流体样品泵送通过流体通道。 另一种技术使用电极来调节物体在流体通道中的位置。 另一种技术通过从检测焦平面反向传播图像波前到不同焦平面,基于杨氏干扰,使用差分干涉对比度(DIC)来计算地调整图像波前的焦平面。 这些技术可以单独使用或组合使用以提高OFM设备的能力。