公开(公告)号：US07388199B2

公开(公告)日：2008-06-17

申请号：US10570198

申请日：2004-09-03

申请人： Takafumi Morimoto ,  Tooru Shinaki ,  Yoshiyuki Nag'No ,  Yukio Kenbou ,  Yuuichi Kunitomo ,  Takenori Hiroki ,  Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Shigeru Miwa ,  Ken Murayama ,  Mitsuo Hayashibara ,  Kishio Hidaka ,  Tadashi Fujieda

发明人： Takafumi Morimoto ,  Tooru Shinaki ,  Yoshiyuki Nag'No ,  Yukio Kenbou ,  Yuuichi Kunitomo ,  Takenori Hiroki ,  Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Shigeru Miwa ,  Ken Murayama ,  Mitsuo Hayashibara ,  Kishio Hidaka ,  Tadashi Fujieda

IPC分类号： G21K7/00

CPC分类号： G01Q70/12

摘要： A probe is made by attaching a carbon nanotube 12 to a mounting base end 13, which eliminates the effects of a carbon contamination film, to increase the bonding strength, increase the conductivity of the probe, and strengthen the bonding performance thereof by coating the entire circumference of the nanotube and the base with a coating film, rather than coating just one side. The work of mounting the carbon nanotube and mounting base end are performed under observation by a microscope. Further, the carbon contamination film 14 formed by an electron microscope is stripped off at a stage before bonding by the coating film.

摘要翻译： 通过将碳纳米管12附着到安装基端13上，从而消除碳污染膜的影响，提高接合强度，提高探针的导电性，并通过涂覆全部 纳米管的周长和基底与涂膜，而不是仅涂覆一面。 在显微镜观察下进行安装碳纳米管和安装基端的工作。 此外，通过电子显微镜形成的碳污染膜14在通过涂膜粘合之前的阶段被剥离。

公开(公告)号：US20060284084A1

公开(公告)日：2006-12-21

申请号：US10570198

申请日：2004-09-03

申请人： Takafumi Morimoto ,  Tooru Seinaki ,  Yoshiyuki Nag-No ,  Yukio Kenbou ,  Yuuichi Xunitomo ,  Takenori Hiroki ,  Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Shigeru Miwa ,  Ken Murayama ,  Mitsuo Hayashirara ,  Kishio Hidaka ,  Tadashi Fujieda

发明人： Takafumi Morimoto ,  Tooru Seinaki ,  Yoshiyuki Nag-No ,  Yukio Kenbou ,  Yuuichi Xunitomo ,  Takenori Hiroki ,  Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Shigeru Miwa ,  Ken Murayama ,  Mitsuo Hayashirara ,  Kishio Hidaka ,  Tadashi Fujieda

IPC分类号： G21K7/00

CPC分类号： G01Q70/12

摘要： A method of producing a probe by attaching a carbon nanotube etc. to a mounting base end and bonding it there using a carbon film etc., which method of producing a probe eliminates the effects of a carbon contamination film to increase the bonding strength, increases the conductivity of the probe, and strengthens the bonding performance by coating the entire circumference rather than coating one side, the probe, and a scanning probe microscope are provided. The method of producing a probe is a method of producing a probe comprised of a carbon nanotube 12, a mounting base ends 13 holding this carbon nanotube, and a coating film 17 bonding the carbon nanotube to a mounting base, comprising performing the mounting work of the carbon nanotube and mounting base end under observation by a microscope and stripping off the carbon contamination film 14 formed by an electron microscope at a stage before bonding by the coating film.

摘要翻译： 通过使用碳膜等将碳纳米管等附接到安装基端并在其上进行接合来制造探针的方法，制造探针的方法消除了碳污染膜的作用，增加了接合强度，增加了 提供探针的导电性，并且通过涂覆整个周边而不是涂覆一侧，探针和扫描探针显微镜来增强粘合性能。 制造探针的方法是制造由碳纳米管12，保持该碳纳米管的安装基端13和将碳纳米管粘合到安装基底的涂膜17的探针的制造方法，其特征在于， 碳纳米管和安装基端通过显微镜观察，并在通过涂膜粘合之前的阶段剥离由电子显微镜形成的碳污染膜14。

公开(公告)号：US07350404B2

公开(公告)日：2008-04-01

申请号：US10569373

申请日：2004-08-27

申请人： Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Yasushi Minomoto ,  Shigeru Miwa ,  Ken Murayama ,  Yukio Kenbou ,  Yuuichi Kunitomo ,  Takenori Hiroki ,  Yoshiyuki Nagano ,  Takafumi Morimoto

发明人： Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Yasushi Minomoto ,  Shigeru Miwa ,  Ken Murayama ,  Yukio Kenbou ,  Yuuichi Kunitomo ,  Takenori Hiroki ,  Yoshiyuki Nagano ,  Takafumi Morimoto

IPC分类号： G21K7/00 ,  G01B5/18

CPC分类号： G01Q10/06 ,  G01Q30/06 ,  Y10T29/49828

摘要： The probe tip movement control method of the scanning probe microscope is used for a scanning probe microscope provided with a cantilever 21 having a probe tip 20 facing a sample 12. The atomic force occurring between the probe tip and sample is measured when the probe tip scans the surface of the sample. X-, Y-, and Z-fine movement mechanisms 23, 29, and 30 are used to relatively change the positions of the probe tip and sample. It is possible to maintain a high measurement accuracy and enable scan movement of a probe tip on a sample surface by simple control when measuring a part having a gradient in measurement of an uneven shape on a sample surface.

摘要翻译： 扫描探针显微镜的探针头移动控制方法用于具有面向样品12的探针尖端20的悬臂21的扫描探针显微镜。 当探针尖端扫描样品的表面时，测量探针尖端和样品之间发生的原子力。 X，Y和Z精细运动机构23,29和30用于相对改变探针尖端和样品的位置。 通过简单的控制，可以在测量样品表面上具有不均匀形状的测量梯度的部分时，保持高测量精度并且能够使探针尖端在样品表面上进行扫描运动。

公开(公告)号：US20050012936A1

公开(公告)日：2005-01-20

申请号：US10893364

申请日：2004-07-19

申请人： Ken Murayama ,  Yukio Kenbou ,  Yuuichi Kunitomo ,  Takenori Hiroki ,  Yoshiyuki Nagano ,  Takafumi Morimoto ,  Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Shigeru Miwa

发明人： Ken Murayama ,  Yukio Kenbou ,  Yuuichi Kunitomo ,  Takenori Hiroki ,  Yoshiyuki Nagano ,  Takafumi Morimoto ,  Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Shigeru Miwa

IPC分类号： G01B21/30 ,  G01B11/24 ,  G01B11/30 ,  G01Q10/04 ,  G01Q20/02 ,  G01Q30/02 ,  G01Q30/04 ,  G01Q30/20 ,  G01Q60/24 ,  H01L21/66

CPC分类号： G01Q20/02 ,  G01Q30/06 ,  G01Q70/04

摘要： A scanning probe microscope has a cantilever with a probe facing a sample and a measurement section for measuring a physical quantity occurring between the probe and the sample when the probe scans a surface of the sample, holding the physical quantity constant to measure the surface of the sample. The above microscope further has a probe tilt mechanism, an optical microscope etc. for detecting a position of the probe when the probe is tilted, and a control section for setting the probe in a first tilt posture and second tilt posture, measuring a surface of the sample by the measurement section at each tilt posture, detecting the position of the probe at least at the second tilt posture by the optical microscope etc., and making a measurement location at the second tilt posture match with a measurement location at the first tilt posture for measurement.

摘要翻译： 扫描探针显微镜具有悬臂，探针面向样品和测量部分，用于测量探头和样品之间发生的物理量，当探针扫描样品的表面时，保持物理量常数以测量样品的表面 样品。 上述显微镜还具有探针倾斜机构，光学显微镜等，用于在探头倾斜时检测探头的位置;以及控制部，用于将探针设置在第一倾斜姿势和第二倾斜姿势中， 通过测量部分在每个倾斜姿势下的样本，至少通过光学显微镜等检测第二倾斜姿势的探测器的位置，并且使第二倾斜姿势的测量位置与第一倾斜处的测量位置匹配 测量姿势。

公开(公告)号：US07333191B2

公开(公告)日：2008-02-19

申请号：US10893364

申请日：2004-07-19

申请人： Ken Murayama ,  Yukio Kenbou ,  Yuuichi Kunitomo ,  Takenori Hiroki ,  Yoshiyuki Nagano ,  Takafumi Morimoto ,  Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Shigeru Miwa

发明人： Ken Murayama ,  Yukio Kenbou ,  Yuuichi Kunitomo ,  Takenori Hiroki ,  Yoshiyuki Nagano ,  Takafumi Morimoto ,  Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Shigeru Miwa

IPC分类号： G01B1/00

CPC分类号： G01Q20/02 ,  G01Q30/06 ,  G01Q70/04

摘要： A scanning probe microscope has a cantilever with a probe facing a sample and a measurement section for measuring a physical quantity occurring between the probe and the sample when the probe scans a surface of the sample, holding the physical quantity constant to measure the surface of the sample. The above microscope further has a probe tilt mechanism, an optical microscope etc. for detecting a position of the probe when the probe is tilted, and a control section for setting the probe in a first tilt posture and second tilt posture, measuring a surface of the sample by the measurement section at each tilt posture, detecting the position of the probe at least at the second tilt posture by the optical microscope etc., and making a measurement location at the second tilt posture match with a measurement location at the first tilt posture for measurement.

摘要翻译： 扫描探针显微镜具有悬臂，探针面向样品和测量部分，用于测量探头和样品之间发生的物理量，当探针扫描样品的表面时，保持物理量常数以测量样品的表面 样品。 上述显微镜还具有探针倾斜机构，光学显微镜等，用于在探头倾斜时检测探头的位置;以及控制部，用于将探针设置在第一倾斜姿势和第二倾斜姿势中， 通过测量部分在每个倾斜姿势下的样本，至少通过光学显微镜等检测第二倾斜姿势的探测器的位置，并且使第二倾斜姿势的测量位置与第一倾斜处的测量位置匹配 测量姿势。

公开(公告)号：US20060284083A1

公开(公告)日：2006-12-21

申请号：US10569373

申请日：2004-08-27

申请人： Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Yasushi Minomoto ,  Shigeru Miwa ,  Ken Murayama ,  Yukio Kenbou ,  Yuuichi Yuuichi ,  Takenori Hiroki ,  Yoshiyuki Nagano ,  Takafumi Morimoto

发明人： Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Yasushi Minomoto ,  Shigeru Miwa ,  Ken Murayama ,  Yukio Kenbou ,  Yuuichi Yuuichi ,  Takenori Hiroki ,  Yoshiyuki Nagano ,  Takafumi Morimoto

IPC分类号： G21K7/00

CPC分类号： G01Q10/06 ,  G01Q30/06 ,  Y10T29/49828

摘要： The probe tip movement control method of the scanning probe microscope is used for a scanning probe microscope provided with a cantilever 21 having a probe tip 20 facing a sample 12. The atomic force occurring between the probe tip and sample is measured when the probe tip scans the surface of the sample. X-, Y-, and Z-fine movement mechanisms 23, 29, and 30 are used to relatively change the positions of the probe tip and sample. It is possible to maintain a high measurement accuracy and enable scan movement of a probe tip on a sample surface by simple control when measuring a part having a gradient in measurement of an uneven shape on a sample surface.

摘要翻译： 扫描探针显微镜的探针头移动控制方法用于具有面向样品12的探针尖端20的悬臂21的扫描探针显微镜。 当探针尖端扫描样品的表面时，测量探针尖端和样品之间发生的原子力。 X，Y和Z精细运动机构23,29和30用于相对改变探针尖端和样品的位置。 通过简单的控制，可以在测量样品表面上具有不均匀形状的测量梯度的部分时，保持高测量精度并且能够使探针尖端在样品表面上进行扫描运动。

公开(公告)号：US20070180889A1

公开(公告)日：2007-08-09

申请号：US10565509

申请日：2004-03-22

申请人： Ken Murayama ,  Yokio Kenbou ,  Yuuichi Kunitomo ,  Takenori Hiroki ,  Yoshiyuki Nagano ,  Takafumi Morimoto ,  Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Shigeru Miwa ,  Takashi Furutani

发明人： Ken Murayama ,  Yokio Kenbou ,  Yuuichi Kunitomo ,  Takenori Hiroki ,  Yoshiyuki Nagano ,  Takafumi Morimoto ,  Tooru Kurenuma ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Shigeru Miwa ,  Takashi Furutani

IPC分类号： G12B21/00 ,  G01N13/10

CPC分类号： G01Q10/06 ,  G01Q30/06 ,  G01Q70/02

摘要： A probe replacement method for a scanning probe microscope for measuring the surface of a sample, having a cantilever (21) having a probe (20), and a measurement unit for measuring a physical quantity between the probe and sample. The scanning probe microscope is provided with a cantilever mount (22), a cantilever cassette (30), an XY stage (14) and Z stage (15) for moving the cantilever cassette, and an optical microscope (18). In a first step, a cantilever is selected from the cantilever cassette and is mounted on the cantilever mount. In a second step, an optical microscope is moved and the mounted cantilever is set in a prescribed position in the field of view after the cantilever is mounted in the scanning probe microscope. In the second step, a step is provided for moving the optical microscope side or the cantilever side and performing positional adjustment.

摘要翻译： 一种用于测量具有具有探针（20）的悬臂（21）的样品表面的扫描探针显微镜的探针替换方法和用于测量探针和样品之间的物理量的测量单元。 扫描探针显微镜具有用于移动悬臂盒的悬臂安装座（22），悬臂盒（30），XY台（14）和Z台（15）以及光学显微镜（18）。 在第一步中，从悬臂盒中选择悬臂，并安装在悬臂安装座上。 在第二步骤中，移动光学显微镜，并且在将悬臂安装在扫描探针显微镜中之后，将安装的悬臂设置在视野中的规定位置。 在第二步骤中，提供移动光学显微镜侧或悬臂侧并执行位置调整的步骤。

公开(公告)号：US20080236259A1

公开(公告)日：2008-10-02

申请号：US11660271

申请日：2005-08-18

申请人： Tooru Kurenuma ,  Yukio Kenbou ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Takafumi Morimoto

发明人： Tooru Kurenuma ,  Yukio Kenbou ,  Hiroaki Yanagimoto ,  Hiroshi Kuroda ,  Takafumi Morimoto

IPC分类号： G01B5/28

CPC分类号： G01Q10/065

摘要： A scanning probe microscope provided with a cantilever 21 having a probe 20 facing a sample 12, a measurement unit 24 measuring a physical quantity occurring between the probe and sample, and movement mechanisms 11, 29 changing a positional relationship between the probe and sample to cause a scanning operation and making the probe scan the surface of the sample by the movement mechanism and measure the surface of the sample by the measurement unit. This method is provided with a step of feeding the probe in a direction along the surface of the sample at a position separate from the surface at certain distances, a step of making the probe approach the sample at each of a plurality of measurement points determined at certain distances and perform measurement to obtain measurement values, then retract, and a step setting a measurement point at a position between a certain measurement point and next measurement point for measurement when a difference between a measurement value at the certain measurement point and a measurement value at the next measurement point is larger than a reference value.

摘要翻译： 具有悬臂21的扫描探针显微镜，其具有面向样品12的探针20，测量在探针和样品之间发生的物理量的测量单元24和改变探针与样品之间的位置关系的移动机构11,29， 扫描操作并使探针通过移动机构扫描样品的表面，并通过测量单元测量样品的表面。 该方法具有以下步骤：沿着与样品表面在一定距离处分开的位置沿着样品表面的方向进给探针，使得探针在多个测量点中的每一个测量点处接近样品的步骤 一定距离并进行测量以获得测量值，然后缩回，并且当在某个测量点处的测量值与测量值之间的差异时，将某个测量点和下一测量点之间的位置处的测量点设置为测量点 在下一个测量点大于参考值。

公开(公告)号：US06317669B1

公开(公告)日：2001-11-13

申请号：US09697423

申请日：2000-10-27

申请人： Tooru Kurenuma ,  Yoshiyuki Nagano ,  Hideto Ishibashi

发明人： Tooru Kurenuma ,  Yoshiyuki Nagano ,  Hideto Ishibashi

IPC分类号： E02F920

CPC分类号： E02F9/2041 ,  E02F3/434 ,  E02F3/438 ,  E02F9/2029

摘要： An automatically operated shovel has a shovel and an automatic operation controller arranged on the shovel to store by a teaching operation plural working positions of the shovel, which comprises at least a digging position, and also to cause by a reproduction operation the shovel to repeatedly perform a series of reproduction operations on the basis of the stored plural working positions. The automatic operation controller is provided with servo control means for outputting, as a servo control quantity, a sum of a compliance control quantity and a pressure control quantity. The compliance control quantity is obtained by multiplying with a stiffness gain a difference between a target position of each operational element of the shovel, the target position comprising angle information indicative of an operational target of the operational element, and a current position of the operational element, the current position comprising current angle information on the operational element. The pressure control quantity is obtained by multiplying with a pressure gain a difference between a target pressure, which serves as a target when the operational element of the shovel is in contact with an object under digging, and a current pressure of the operational element. The stiffness gain and the pressure gain are settable at varied values depending on the working positions.

摘要翻译： 自动操作的铲铲具有铲子和自动操作控制器，其布置在挖掘机上以通过教学操作存储铲斗的多个工作位置，其至少包括挖掘位置，并且还通过铲斗重复执行的再现操作 基于存储的多个工作位置进行一系列再现操作。 自动操作控制器设置有用于作为伺服控制量输出合规控制量和压力控制量的总和的伺服控制装置。 通过将刚度增益与挖掘机的每个操作元件的目标位置之差（包括指示操作元件的操作目标的角度信息的目标位置）与操作元件的当前位置 当前位置包括关于操作元件的当前角度信息。 压力控制量通过将当铲斗的操作元件与挖掘物体接触的目标压力作为目标压力与作业元件的当前压力之间的压力乘以压力增益而获得。 刚度增益和压力增益可根据工作位置设定在不同的值。

公开(公告)号：US06782644B2

公开(公告)日：2004-08-31

申请号：US10343414

申请日：2003-01-30

申请人： Kazuo Fujishima ,  Tooru Kurenuma ,  Hiroshi Ogura ,  Hideto Ishibashi

发明人： Kazuo Fujishima ,  Tooru Kurenuma ,  Hiroshi Ogura ,  Hideto Ishibashi

IPC分类号： E02F502

CPC分类号： E02F9/2285 ,  E02F3/435 ,  E02F3/437 ,  E02F9/2033 ,  E02F9/205 ,  E02F9/2296 ,  E02F9/261 ,  E02F9/264 ,  G08C17/02 ,  H04Q9/10

摘要： A hydraulic excavator 1 has an area limiting excavation control function for controlling operation of a front working device so as to form a target work plane. A remote control terminal 102 for wirelessly maneuvering the hydraulic excavator 1 is provided in a management office so that entry of setting information of a target excavation plane and remote maneuvering can be performed from the side of the remote control terminal 102. A display unit 71b for displaying a positional relationship between the hydraulic excavator 1 and the target excavation plane is further provided in the remote control terminal. An operator can remotely set the target excavation plane while looking at a screen of the display unit 71b, and also form the target excavation plane by remotely maneuvering the front working device 7 using a joystick 72 with the aid of a control function of an area limiting excavation controller. As a result, the remote setting of the target excavation plane and the remote maneuvering of the hydraulic excavator 1 can be easily performed.

摘要翻译： 液压挖掘机1具有区域限制挖掘控制功能，用于控制前工作装置的操作以形成目标工作平面。 用于无线操纵液压挖掘机1的遥控终端102设置在管理办公室中，使得可以从遥控终端102侧进入目标挖掘平面的设置信息和远程操纵。一个显示单元71b，用于 显示液压挖掘机1与目标挖掘平面之间的位置关系进一步设置在遥控终端中。 操作员可以在观察显示单元71b的屏幕的同时远程设置目标挖掘平面，并且借助于区域限制的控制功能使用操纵杆72远程操纵前作业装置7来形成目标挖掘平面 挖掘控制器。 因此，能够容易地进行目标挖掘机的远程设定和液压挖掘机1的远程操纵。