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    • 1. 发明公开
    • 감염성 미생물을 검지하는 광학 바이오센서
    • 用于检测感染性微生物的光学生物传感器
    • KR1020170119448A
    • 2017-10-27
    • KR1020160047463
    • 2016-04-19
    • 한국생명공학연구원
    • 신용범조나래이기중
    • G01N21/53G01N33/569
    • G01N21/532G01N33/569G01N33/56983
    • 본발명은, 감염성미생물을검지하는광학바이오센서에있어서, 광원; 광원에서방출된광이투과되고미세홈이장주기로배열되며대기중의바이러스가상기미세홈의내측으로포집되는센서칩; 및센서칩을투과한광이조영되어미세홈의내측에상기바이러스가포집된상태를가시적으로나타내는디스플레이기판을포함하고, 미세홈은 0.5um 이상의간격을갖는장주기로배열되어, 디스플레이기판에미세홈의간격간 광의분해능이확보될수 있다. 본발명에따르면, 미세홈이광학적회절한계를벗어나는장주기로배열되어미세홈 간격간 광의분해능이확보된다. 따라서, 감염성미생물이미세홈에포획되면이를가시적으로즉시확인이가능한이점이있다. 결국본 발명은감염성바이러스로인한감염공간의격리와피해자의확산방지가신속히요구되는상황에서특히적합하다.
    • 本发明提供了用于检测感染性微生物的光学生物传感器,其包括:光源; 一种传感器芯片,通过该传感器芯片,光源发出的光透过并以细槽周期排列,并且空气中的病毒被收集在细槽内; 和被布置在循环部分通过所述传感器芯片汉王yijoyoung包括指示病毒的被捕获在的微细凹槽可见状态下的内部的显示基板传送,并且细槽具有一个距离大于0.5微米以上时,细槽的显示基板上的间隔 光的分辨率可以得到保证。 根据本发明,由于微细槽以偏离衍射极限的长周期配置,所以能够确保细槽间的光的分辨率。 因此,当感染性微生物被捕获在微细沟槽中时,可以立即目视确认它们。 结果,本发明特别适用于需要感染性病毒来隔离感染空间并快速防止受害者扩散的情况。
    • 4. 发明公开
    • 가스의 레이저 분광을 위한 방법
    • 气体激光光谱法
    • KR1020140032898A
    • 2014-03-17
    • KR1020130104881
    • 2013-09-02
    • 식아게
    • 바이엘,토마스이들러,줄리안
    • G01N21/25
    • G01N21/255G01J3/28G01J3/433G01N21/274G01N21/3504G01N21/39G01N2021/399G01N2201/0691G01N2201/1211G01N2201/1215G01N2201/1218G01N21/00G01N7/00G01N21/25G01N21/532G01N21/59G01N21/5907G01N21/78G01N21/783
    • A method for determining the composition and/or the concentration of gas in a sample using a spectrometer comprises: a step of measuring the adsorption signals of gas as a wavelength function; a step of converting the adsorption signals to one or more first induction signals; a step of inducing gas concentration measuring parameters from the first induction signals; and a step of determining the composition and/or the concentration of the gas from a calibration function which can compensate influences caused by the gas concentration measuring parameters, the parameters of device properties of the spectrometer, and the parameters of gas stages. In the step of measuring the adsorption signals of the gas, wavelengths continuously pass within a wavelength range, and are overlapped by harmonic wavelength modulation. Also, the influences of the wavelength modulation about the adsorption signals through light source modulation properties and the detection properties of the spectrometer follow the device properties of the spectrometer. The calibration function includes a parent calibration function and a device calibration function. Herein, one or more gas concentration measuring parameters induced from the induction signals and the parameters of the gas states are applied to the parent calibration function and are selected to compensate the light source modulation properties of the spectrometer. Also, the device calibration function considers the detection properties of the spectrometer. [Reference numerals] (13) Device properties; (14) Light source modulation properties; (15) Number of particles (N); (16) Detection properties; (17') Section y'f signal {F(y'f)}; (21) Concentration; (23) Ratio {V=F(xf)/F(yf)}; (25) Width xf signal {B(zf)}; (27) Parent calibration function {K_M(p, T, X, F, V, B)}; (29) Device calibration function (K_G); (AA) Pressure (p); (BB) Temperature (t); (CC) Carrier gas (X); (DD) Section xf signal {F(xf)}; (EE) Section yf signal {f(yf)}
    • 使用光谱仪测定样品中的组成和/或浓度的方法包括:测量作为波长函数的气体的吸附信号的步骤; 将吸附信号转换成一个或多个第一感应信号的步骤; 从第一感应信号诱导气体浓度测量参数的步骤; 以及从校正功能确定气体的组成和/或浓度的步骤,该校准功能可以补偿由气体浓度测量参数,光谱仪的装置特性参数和气相参数引起的影响。 在测量气体的吸附信号的步骤中,波长在波长范围内连续通过,并与谐波波长调制重叠。 此外,通过光源调制性质的光吸收信号的波长调制和光谱仪的检测特性的影响遵循光谱仪的器件特性。 校准功能包括父校准功能和设备校准功能。 这里,将从诱导信号和气体状态的参数引起的一个或多个气体浓度测量参数应用于母体校准功能,并且被选择以补偿光谱仪的光源调制性质。 此外,器件校准功能考虑了光谱仪的检测特性。 (附图标记)(13)装置特性; (14)光源调制性能; (15)颗粒数(N); (16)检测属性; (17')部分y'f信号{F(y'f)}; (21)浓度; (23)比率{V = F(xf)/ F(yf)}; (25)宽xf信号{B(zf)}; (27)父校准函数{K_M(p,T,X,F,V,B)}; (29)设备校准功能(K_G); (AA)压力(p); (BB)温度(t); (CC)载气(X); (DD)部分xf信号{F(xf)}; (EE)部分yf信号{f(yf)}
    • 6. 发明授权
    • 먼지 측정이 가능한 이동 단말기 및 먼지 데이터 제공시스템 및 그 방법
    • 测量灰尘的移动终端和用于提供灰尘数据的方法和装置
    • KR100797372B1
    • 2008-01-22
    • KR1020070033661
    • 2007-04-05
    • 에스케이텔레콤 주식회사
    • 김진식
    • H04B1/40
    • H04M1/72569G01N15/06G01N21/532H04M2250/12
    • A mobile terminal capable of measuring dust, a dust data service system, and a method thereof are provided to generate scattered light pulses by irradiating light as heating the air, and to take a picture of the scattered light pulses as analyzing the taken picture, thereby extracting an amount of dust. An air heater(110) heats the air by being comprised at a predetermined position of a mobile terminal(100). A light source(130) is installed in the vicinity of the air heater(110), and irradiates light on the heated air to generate scattered light pulses. A camera(120) takes a picture of the scattered light pulses. A storage(150) stores image data taken with the camera(120) together with measurement time.
    • 提供能够测量灰尘的移动终端,灰尘数据服务系统及其方法,以通过在加热空气时照射光来产生散射光脉冲,并且对散射的光脉冲进行分析以拍摄照片,从而 提取一定量的粉尘。 空气加热器(110)通过包括在移动终端(100)的预定位置来加热空气。 光源(130)安装在空气加热器(110)附近,并将光照射在加热的空气上,产生散射光脉冲。 相机(120)拍摄散射光脉冲的图像。 存储器(150)存储与摄像机(120)拍摄的图像数据以及测量时间。
    • 7. 发明公开
    • 투과형 광학식 먼지 감지장치
    • 传输型光学检测装置
    • KR1020160109120A
    • 2016-09-21
    • KR1020150032971
    • 2015-03-10
    • 주식회사 트루윈
    • 박정근김지현
    • G01N15/06G01N15/02G01N21/53
    • G01N15/06G01N15/0205G01N21/532G01N2015/0693
    • 본발명은투과방식으로먼지를감지하도록구성하고입사광의일부를측정하여입사광량의변화를측정값에반영하여보다정밀한측정결과를얻을수 있는투과형광학식먼지감지장치를제공한다. 본발명의투과형광학식먼지감지장치는케이스와, 케이스의내부한쪽에설치되고빛을조사하는발광부와, 발광부와간격을두고케이스의내부에설치되며발광부에서조사된빛의일부는반사하고나머지는투과시키는빔스플리터와, 발광부와각도를갖고케이스의내부에설치되며빔스플리터에서반사되는빛을감지하는조절수광부와, 케이스의내부에설치되며빔스플리터를투과한빛을집광하는집광렌즈와, 집광렌즈의초점거리보다더 먼거리에발광부와일직선상의반대편에케이스의내부에설치되어집광렌즈를통과한빛을감지하는측정수광부를포함한다.
    • 本发明提供了一种透射型光学尘埃检测装置,其通过透射法检测灰尘,测量入射光的一部分,将入射光量的变化反映到测量值,并获得更精确的测量结果。 根据本发明的透射型光学尘埃检测装置包括:壳体; 安装在壳体的一侧的发光单元和照射光; 光束分离器,其安装在发光单元与其间的间隔的情况下,反射从发光单元照射的光的一部分,并传输剩余的光; 调节光接收单元,其相对于所述发光单元以一定角度安装在所述壳体中,并且感测从所述分束器反射的光; 安装在壳体中的聚光透镜,以及透射通过分束器的聚光; 以及测量光接收单元,其安装在所述发光单元的线上的相对侧的壳体中,以远于所述聚光透镜的焦距,并且感测通过所述聚光透镜的光。
    • 8. 发明公开
    • 먼지 센서의 출력 보정 방법
    • 感测方法
    • KR1020160106908A
    • 2016-09-13
    • KR1020150029603
    • 2015-03-03
    • 쌍신전자통신주식회사
    • 이태휘박세범
    • G01N15/06G01N15/02G01N21/53
    • G01N15/06G01N15/0205G01N21/532G01N2015/0693
    • 먼지센서의출력기준값을조절하는방법이개시된다. 본발명의먼지센서의출력방법은마스터센서로먼지가투입된챔버내의먼지농도를측정하여마스터값을측정하는단계; 측정센서에저장된출력기준값으로출력되는센서값을측정하는단계; 상기측정센서에서측정된센서값과마스터값의평균값을산출하는단계; 상기평균값과마스터값을이용하여보정값을산출하는단계; 상기보정값의기 설정된기준값을비교하는단계; 및상기보정값의절대값이상기기준값보다크면상기출력기준값을갱신하는단계를포함할수 있다.
    • 公开了一种用于调整灰尘传感器中的输出标准值的方法。 本发明的尘埃传感器的输出方法包括以下步骤:通过测量将灰尘插入主传感器的室内的灰尘浓度来测量主值; 测量传感器值输出作为存储在测量传感器中的输出标准值; 计算在测量传感器中测量的主值和传感器值的平均值; 使用平均值和主值计算校正值; 比较校正值的预定标准值; 以及如果所述校正值的绝对值大于所述标准值,则更新所述输出标准值。
    • 9. 发明公开
    • 원격검출용 주파수 및 강도 변조 레이저 흡수 분광장치 및 방법
    • 频率和强度调制激光吸收光谱仪和远程气体检测方法
    • KR1020160085548A
    • 2016-07-18
    • KR1020150002678
    • 2015-01-08
    • 한국표준과학연구원
    • 이재용김재완박정재우제흔
    • G01N21/17G01N21/39G01N21/53G01J3/42
    • G01J3/42G01N21/17G01N21/39G01N21/53G01N21/532G01N21/55
    • 본발명은광주파수/강도변조레이저흡수분광장치및 광주파수/강도변조레이저흡수분광방법을제공한다. 이광주파수/강도변조레이저흡수분광장치는측정대상에프로브빔을제공하고소정의주파수대역에서변조주파수(f)로상기프로브빔의광주파수를변조하고상기변조주파수(f)로상기프로브빔의강도를변조하는레이저광원부; 상기측정대상에서반사, 투과, 또는산란된프로브빔을전기신호로변환하는광감지부; 및상기광감지부의출력신호인레이저흡수신호를처리하여상기변조주파수(f)의 1차고주파성분(M) 및상기변조주파수(f)의 2차고조파성분(M)을추출하고상기변조주파수(f)의 1차고조파성분(M)과상기변조주파수의 2차고조파성분(M)의비(M/M)를이용하여상기측정대상에의한상기프로브빔의흡수도를산출하는처리부를포함한다.
    • 本发明提供光频率和强度调制激光吸收光谱装置以及光频率和强度调制激光吸收光谱法。 光频率和强度调制激光吸收光谱装置包括:激光光源单元,向待测对象提供探测光束,使用调制频率(f_m)在预定频带中调制探测光束的光频;以及调制 使用调制频率(f_m)的探测光束的强度; 光检测单元将被测量对象中被反射,穿透或散射的探测光束变更为电信号; 以及处理单元,通过处理作为调制频率(f_m)的输出信号的激光吸收信号来提取调制频率(f_m)的第一高次谐波分量(M_1)和调制频率(f_m)的次高次谐波分量(M_2) 光检测单元,并且通过使用调制频率(f_m)的第一高次谐波分量(M_1f)与第二高次谐波分量(M_2f)的比率来计算待测对象的探测光束的吸收度 )调制频率。
    • 10. 发明公开
    • 탁도계
    • 浊度仪
    • KR1020140094454A
    • 2014-07-30
    • KR1020140006100
    • 2014-01-17
    • 가부시키가이샤 호리바 어드밴스트 테크노
    • 스즈키리이치로기자키히로코마쓰오아키간다히로시
    • G01N21/49G01N21/59
    • G01N21/51G01N21/532
    • A terbidimeter has a simple and strong structure not to often malfunction and reduced number of seal parts, thereby obtaining excellent long-term stability. A cylindrical sensor head (4) forming a measurement space (Sa) is formed of a light-transmittable material. The side wall (42) of the sensor head (4) has receiving spaces (Sb1-Sb3) for receiving a light source (5), a transmitted light detector (6), and a scattered light detector (7). The inner surface of the side wall (42) of the sensor head (4) becomes an optical window (M1) for inducing inspection light (L1) to the measurement space (Sa), an optical window (M2) for inducting transmitted light (L2) to the transmitted light detector (6), and an optical window (M3) for inducing scattered light (L3) to the scattered light detector (7).
    • 特比计具有简单而坚固的结构,不会经常发生故障并减少密封件的数量,从而获得优异的长期稳定性。 形成测量空间(Sa)的圆柱形传感器头(4)由透光材料形成。 传感器头(4)的侧壁(42)具有用于接收光源(5)的接收空间(Sb1-Sb3),透射光检测器(6)和散射光检测器(7)。 传感器头(4)的侧壁(42)的内表面成为用于将检测光(L1)引导到测量空间(Sa)的光学窗口(M1),用于感应透射光的光学窗口(M2) L2)发送到透射光检测器(6),以及用于将散射光(L3)引导到散射光检测器(7)的光学窗口(M3)。