公开(公告)号：US20110075143A1

公开(公告)日：2011-03-31

申请号：US12992473

申请日：2009-05-07

Applicant: Katsumi Shibayama ,  Takashi Kasahara ,  Anna Yoshida

Inventor： Katsumi Shibayama ,  Takashi Kasahara ,  Anna Yoshida

IPC: G01J3/18 ,  B29D11/00

CPC classification number: G01J3/0205 ,  G01J3/02 ,  G01J3/0208 ,  G01J3/0243 ,  G01J3/0259 ,  G01J3/0262 ,  G01J3/04 ,  G01J3/18 ,  G01J3/2803 ,  G02B7/027 ,  H01L31/18

Abstract: The present invention provides a highly reliable spectral module. When light L1 proceeding to a spectroscopic unit (4) passes through a light transmitting hole (50) in the spectral module (1) in accordance with the present invention, only the light having passed through a light entrance side unit (51) formed such as to become narrower toward a substrate (2) and entered a light exit side unit (52) formed such as to oppose a bottom face (51b) of the light entrance side unit (51) is emitted from a light exit opening (52a). Therefore, stray light M incident on a side face (51c) or bottom face (51b) of the light entrance side unit (51) is reflected to the side opposite to the light exit side unit (52) and thus is inhibited from entering the light exit side unit (52). Therefore, the reliability of the spectral module (1) can be improved.

Abstract translation: 本发明提供了一种高度可靠的光谱模块。 当进入分光单元（4）的光L1穿过根据本发明的光谱模块（1）中的透光孔（50）时，仅通过形成光入射侧单元（51）的光 朝向基板（2）变窄并且进入与光入射侧单元（51）的底面（51b）相对形成的光出射侧单元（52）从光出射开口（52a）射出， 。 因此，入射到光入射单元（51）的侧面（51c）或底面（51b）的杂散光M被反射到与光出射单元（52）相反的一侧，因此被禁止进入 光出射侧单元（52）。 因此，可以提高光谱模块（1）的可靠性。

公开(公告)号：US20100201980A1

公开(公告)日：2010-08-12

申请号：US12377325

申请日：2008-06-05

Applicant: Katsumi Shibayama ,  Takafumi Yokino ,  Tomofumi Suzuki ,  Helmut Teichmann ,  Dietmar Hiller ,  Ulrich Starker

Inventor： Katsumi Shibayama ,  Takafumi Yokino ,  Tomofumi Suzuki ,  Helmut Teichmann ,  Dietmar Hiller ,  Ulrich Starker

IPC: G01J3/28

CPC classification number: G01J3/04 ,  G01J3/02 ,  G01J3/0202 ,  G01J3/0243 ,  G01J3/0259 ,  G01J3/0262 ,  G01J3/0291 ,  G01J3/18 ,  G01J3/2803

Abstract: In the spectroscopy module 1, a light absorbing layer 6 having a light-passing hole 6a through which light L1 advancing into a spectroscopic portion 3 passes and a light-passing hole 6b through which light L2 advancing into a light detecting portion 4a of a light detecting element 4 passes is integrally formed by patterning. Therefore, it is possible to prevent deviation of the relative positional relationship between the light-passing hole 6a and the light-passing hole 6b. Further, since the occurrence of stray light is suppressed by the light absorbing layer 6 and the stray light is absorbed, the light detecting portion 4a of the light detecting element 4 can be suppressed from being made incident. Therefore, according to the spectroscopy module 1, it is possible to improve the reliability.

Abstract translation: 在光谱模块1中，具有通过光入射到分光部3的光L1通过的光通过孔6a的光吸收层6和通过光进入光的光检测部4a的光通过孔6b 检测元件4通过图案化一体地形成。 因此，可以防止通光孔6a和通光孔6b之间的相对位置关系的偏差。 此外，由于光吸收层6抑制了杂散光的发生，并且杂散光被吸收，所以能够抑制光检测元件4的光检测部4a的入射。 因此，根据光谱模块1，可以提高可靠性。

公开(公告)号：US20100183044A1

公开(公告)日：2010-07-22

申请号：US12663838

申请日：2008-06-12

Applicant: Hideki Tanaka

Inventor： Hideki Tanaka

IPC: G01J5/00 ,  G01J5/02

CPC classification number: G01J5/04 ,  G01J3/0202 ,  G01J3/0243 ,  G01J5/0011 ,  G01J5/02 ,  G01J5/0205 ,  G01J5/025 ,  G01J5/028 ,  G01J5/048 ,  G01J5/049 ,  G01J5/08 ,  G01J5/085 ,  G01J5/14 ,  G01J2005/068 ,  H05K1/189 ,  H05K2201/09063 ,  H05K2201/10151 ,  H05K2201/10606

Abstract: An object is to realize an ear thermometer that is configured to easily arrange a sensor in a sensor mirror and is suitable for mass production. The ear thermometer has a probe. The probe includes a probe body and a temperature measuring part joined with the probe body. The temperature measuring part includes a flange coupled with the probe body and a front end part extending from the flange, the front end part incorporating a sensor mirror. The sensor mirror includes a cylindrical holder with an internal concave reflection face, a connection shaft extending from the back of the cylindrical holder, a flexible printed circuit board with a circuit conductor of predetermined pattern, stretched in a front space of the cylindrical holder, a temperature measuring first sensor and a correcting second sensor spaced by a predetermined distance from each other in a longitudinal direction of the board and soldered to the circuit conductor on the board, and a protection cover covering a front face of the cylindrical holder. The board is electrically connected, in the temperature measuring part, to the cable passing through the probe body.

Abstract translation: 一个目的是实现一种耳式温度计，其配置为能够将传感器轻松地布置在传感器镜中，并且适合于批量生产。 耳温度计有一个探头。 探针包括探针体和与探针体接合的温度测量部。 温度测量部件包括与探针本体连接的凸缘和从凸缘延伸的前端部，前端部分包括传感器镜。 传感镜包括一个带有内凹反射面的圆筒形保持器，从圆柱形保持器的后面延伸的连接轴，具有预定图案的电路导体的柔性印刷电路板，在柱形保持器的前部空间中被拉伸， 温度测量第一传感器和校正第二传感器，其在板的纵向方向上彼此间隔开预定距离并且焊接到板上的电路导体，以及覆盖圆柱形保持器的前表面的保护盖。 该板在温度测量部分电连接到穿过探头主体的电缆。

公开(公告)号：US20090284742A1

公开(公告)日：2009-11-19

申请号：US12465245

申请日：2009-05-13

Applicant: Katsumi SHIBAYAMA

Inventor： Katsumi SHIBAYAMA

IPC: G01J3/28

CPC classification number: G01J3/2803 ,  G01J3/02 ,  G01J3/0202 ,  G01J3/0208 ,  G01J3/0218 ,  G01J3/0243 ,  G01J3/0256 ,  G01J3/0262 ,  G01J3/0291 ,  G01J3/18

Abstract: In the spectrometer 1, a lens portion 3 having a spherical surface 35 on which a spectroscopic portion 4 is provided and a bottom plane 31 in which a light detecting element 5 is disposed, has a side plane 32 substantially perpendicular to the bottom plane 31 and a side plane 34 substantially perpendicular to the bottom plane 31 and the side plane 32. Then, a package 11 that houses a spectroscopy module 10 has side planes 16 and 18 respectively coming into planar-contact with the side planes 32 and 34, and contact portions 22 coming into contact with the spherical surface 35. Therefore, the side planes 32 and 34 of the lens portion 3 are respectively brought into planar-contact with the side planes 16 and 18 of the package 11 while bringing the spherical surface 35 of the lens portion 3 into contact with the contact portions 22 of the package 11, that positions the spectroscopic portion 4 and the light detecting element 5 with respect to a light incident window plate 25 of the package 11.

Abstract translation: 在分光计1中，具有设置有分光部4的球面35的透镜部3和设置有光检测元件5的底面31具有大致垂直于底面31的侧面32， 基本上垂直于底平面31和侧平面32的侧平面34.然后，容纳光谱模块10的封装11具有分别与侧平面32和34平面接触的侧平面16和18，并且接触 部分22与球面35接触。因此，透镜部分3的侧面32和34分别与包装11的侧面16和18平面接触，同时使 透镜部分3与封装11的接触部分22接触，其将分光部分4和光检测元件5相对于封装的光入射窗板25定位 11。

公开(公告)号：US20090213377A1

公开(公告)日：2009-08-27

申请号：US12463550

申请日：2009-05-11

Applicant: David SCHEINER ,  Michael Winik ,  Yakov Lyubchik

Inventor： David SCHEINER ,  Michael Winik ,  Yakov Lyubchik

IPC: G01J4/00

CPC classification number: G02B21/16 ,  G01J3/0205 ,  G01J3/021 ,  G01J3/0224 ,  G01J3/0243 ,  G01N21/211 ,  G01N21/47 ,  G01N21/956 ,  G02B17/06 ,  G02B17/0605 ,  G02B19/0023 ,  G02B19/0047 ,  G02B19/0095 ,  G02B21/04 ,  G02B27/10 ,  G02B27/283

Abstract: A lens arrangement is presented. The lens arrangement comprises a first element having a concave reflective surface and defining an optical axis of the lens arrangement, and a second substantially flat and at least partially reflective element spaced-apart from the first element along the optical axis. The second element is configured to allow light passage therethrough and is oriented with respect to the optical axis and the first element such that at a predetermined angle of incidence of an input light beam onto the second element, the input light beam is reflected onto the reflective surface of the first element and reflected therefrom to pass through the second element.

Abstract translation: 呈现镜头布置。 透镜装置包括具有凹面反射表面并限定透镜装置的光轴的第一元件以及沿着光轴与第一元件间隔开的第二基本平坦且至少部分反射的元件。 第二元件被配置为允许光通过其并且相对于光轴和第一元件定向，使得在输入光束到第二元件的预定入射角度处，输入光束被反射到反射 第一元件的表面并从其反射以穿过第二元件。

公开(公告)号：US07531802B2

公开(公告)日：2009-05-12

申请号：US11610824

申请日：2006-12-14

Applicant: Xi-Cheng Zhang ,  Jianming Dai ,  Xu Xie

Inventor： Xi-Cheng Zhang ,  Jianming Dai ,  Xu Xie

IPC: G01N21/35

CPC classification number: G01V8/005 ,  G01J3/02 ,  G01J3/0243 ,  G01J3/42 ,  G01N21/3563 ,  G01N21/3581 ,  G01N21/636 ,  G01S7/4802 ,  G01S13/887 ,  G01S17/026 ,  G02F1/353 ,  G02F2203/13

Abstract: A method of analyzing a remotely-located object includes the steps of inducing a volume of an ionized ambient gas to emit pulsed terahertz radiation directed toward a targeted object by focusing an optical pump beam in the volume and ionizing another volume of the ambient gas to produce a sensor plasma by focusing an optical probe beam in the other volume of ambient gas. The interaction, in the sensor plasma, of the focused optical probe beam and an incident terahertz wave, which is produced by the targeted object reflecting, scattering, or transmitting the pulsed terahertz radiation, produces a resultant radiation. Detecting an optical component of the resultant radiation emitted by the sensor plasma facilitates detection of a signature of the targeted object imposed onto the incident terahertz radiation.

Abstract translation: 分析远程物体的方法包括以下步骤：通过将光泵浦光束聚焦在体积中并使另一体积的环境气体电离以产生电离环境气体的体积，以发射朝向目标物体的脉冲太赫兹辐射 通过将光学探针光束聚焦在另一体积的环境气体中的传感器等离子体。 在传感器等离子体中，由目标物体反射，散射或传输脉冲太赫兹辐射产生的聚焦光学探针光束和入射的太赫兹波的相互作用产生合成的辐射。 检测由传感器等离子体发射的辐射的光学部件有助于检测施加在入射的太赫兹辐射上的目标物体的签名。

公开(公告)号：US07511829B2

公开(公告)日：2009-03-31

申请号：US11889112

申请日：2007-08-09

Applicant: Noam Babayoff

Inventor： Noam Babayoff

IPC: G01B11/24

CPC classification number: H04N13/15 ,  A61B1/00009 ,  A61B1/00096 ,  A61B1/0615 ,  A61B1/0638 ,  A61B1/0646 ,  A61B1/0676 ,  A61B1/0684 ,  A61B1/24 ,  A61B1/247 ,  A61B5/0068 ,  A61B5/0088 ,  A61B5/1077 ,  A61B5/1079 ,  A61C9/0053 ,  A61C9/0066 ,  A61C19/04 ,  G01B11/24 ,  G01B11/25 ,  G01J3/02 ,  G01J3/0205 ,  G01J3/0208 ,  G01J3/0216 ,  G01J3/0218 ,  G01J3/0224 ,  G01J3/0243 ,  G01J3/0256 ,  G01J3/10 ,  G01J3/462 ,  G01J3/50 ,  G01J3/501 ,  G01J3/508 ,  G01J3/51 ,  G01N21/255 ,  G06F19/00 ,  G06T7/0012 ,  G06T7/12 ,  G06T7/90 ,  G06T2207/10024 ,  G06T2207/10028 ,  G06T2207/30036 ,  H01L27/14868 ,  H04N13/207 ,  H04N13/257 ,  H04N13/271 ,  H04N13/296

Abstract: A device for determining the surface topology and associated color of a structure, such as a teeth segment, includes a scanner for providing depth data for points along a two-dimensional array substantially orthogonal to the depth direction, and an image acquisition means for providing color data for each of the points of the array, while the spatial disposition of the device with respect to the structure is maintained substantially unchanged. A processor combines the color data and depth data for each point in the array, thereby providing a three-dimensional color virtual model of the surface of the structure. A corresponding method for determining the surface topology and associated color of a structure is also provided.

公开(公告)号：US20070064229A1

公开(公告)日：2007-03-22

申请号：US11599906

申请日：2006-11-15

Applicant: Adam Norton ,  Kenneth Johnson ,  Fred Stanke

Inventor： Adam Norton ,  Kenneth Johnson ,  Fred Stanke

IPC: G01J3/28 ,  G01N21/88

CPC classification number: G01J3/02 ,  G01J3/0224 ,  G01J3/0243 ,  G01J3/28 ,  G01N21/21 ,  G01N21/31 ,  G01N21/956 ,  G01N2021/213 ,  G02B5/3083 ,  G02B27/28 ,  G02B27/286 ,  G02B27/288 ,  G03F7/70625 ,  G03F7/70991

Abstract: A small-spot imaging, spectrometry instrument for measuring properties of a sample has a polarization-scrambling element, such as a birefringent plate depolarizer, incorporated between the polarization-introducing components of the system, such as the beamsplitter, and the microscope objective of the system. The plate depolarizer varies polarization with wavelength, and may be a Lyot depolarizer with two plates, or a depolarizer with more than two plates (such as a three-plate depolarizer). Sinusoidal perturbation in the resulting measured spectrum can be removed by data processing techniques or, if the depolarizer is thick or highly birefringent, the perturbation may be narrower than the wavelength resolution of the instrument.

公开(公告)号：US07158229B2

公开(公告)日：2007-01-02

申请号：US11399133

申请日：2006-04-06

Applicant: Adam E. Norton ,  Kenneth C. Johnson ,  Fred E. Stanke

Inventor： Adam E. Norton ,  Kenneth C. Johnson ,  Fred E. Stanke

IPC: G01J3/28

CPC classification number: G01J3/02 ,  G01J3/0224 ,  G01J3/0243 ,  G01J3/28 ,  G01N21/21 ,  G01N21/31 ,  G01N21/956 ,  G01N2021/213 ,  G02B5/3083 ,  G02B27/28 ,  G02B27/286 ,  G02B27/288 ,  G03F7/70625 ,  G03F7/70991

Abstract: A small-spot imaging, spectrometry instrument for measuring properties of a sample has a polarization-scrambling element, such as a birefringent plate depolarizer, incorporated between the polarization-introducing components of the system, such as the beamsplitter, and the microscope objective of the system. The plate depolarizer varies polarization with wavelength, and may be a Lyot depolarizer with two plates, or a depolarizer with more than two plates (such as a three-plate depolarizer). Sinusoidal perturbation in the resulting measured spectrum can be removed by data processing techniques or, if the depolarizer is thick or highly birefringent, the perturbation may be narrower than the wavelength resolution of the instrument.

公开(公告)号：US07119904B2

公开(公告)日：2006-10-10

申请号：US10755928

申请日：2004-01-13

Applicant: John M. Coffin ,  Robert R. Badeau ,  Michael R. Daun

Inventor： John M. Coffin ,  Robert R. Badeau ,  Michael R. Daun

IPC: G01B9/02

CPC classification number: G01J1/32 ,  G01J3/0243 ,  G01J3/108 ,  G01N2021/3595

Abstract: An infrared spectrometer includes an infrared source system that is stabilized to provide a substantially constant output light intensity. The infrared source system includes a source element adapted to receive electrical power and to emit light at an intensity related to the electrical power received by the source element. A light detector is mounted in position to receive light emitted from the source element and to provide an output signal related to the intensity of the light received by the detector. A feedback control loop receives the signal from the detector and provides electrical power to the source element to maintain the intensity of the light output from the source element at a selected level as detected by the detector.

Abstract translation: 红外光谱仪包括被稳定以提供基本恒定的输出光强度的红外源系统。 红外源系统包括适于接收电功率并以与源元件接收的电功率相关的强度发光的源元件。 光检测器安装在适当位置以接收从源元件发射的光并且提供与由检测器接收的光的强度相关的输出信号。 反馈控制回路接收来自检测器的信号，并向源元件提供电功率，以将来自源元件的光输出的强度保持在由检测器检测到的选定电平。