| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 141 | 电脑机箱(框图-39) | CN201230418826.1 | 2012-09-03 | CN302190241S | 2012-11-21 | 罗润升 |
| 1.该外观设计的产品名称:电脑机箱(框图-39)。2.该外观设计产品的用途:用于保护计算机主机内部组件。3.外观设计的设计要点:该产品的设计要点在于产品的外部造型。4.立体图最能表明设计要点的图片或者照片。 | ||||||
| 142 | Profit/fund block diagram chart, profit/fund block diagram chart preparation device, profit/fund block diagram chart preparation method and recording medium | JP2002009252 | 2002-01-17 | JP2003216794A | 2003-07-31 | MOTOI KEIJI |
| <P>PROBLEM TO BE SOLVED: To provide a profit/fund block diagram chart capable of clearly describing cash flow conditions, providing a sufficient indicator for cash flow management and clearly describing 'where have produced profits gone?'. <P>SOLUTION: In the lower side vertical direction of a present term profit column, a 'depreciation expense' column, a 'reserve fund transfer' column, a 'fixed asset sale income' column, an 'F.C.F' (free cash flow: pure cash income and expenditure) column, a 'loan collection income' column, a 'debt borrowed income' column, a 'discounted bill increase/decrease' column, an 'other income' column and a 'total A' column are arranged. In the right side vertical direction, an 'operation fund increase/decrease' column, a 'business income and expenditure' column, a 'capital spending' column, a 'securities purchase' column, an 'other investment' column, an 'F.C.F' column, a 'loan expenditure' column, a 'debt payment' column, a 'previous term profit appropriation' column, a 'cash deposit increase/decrease' column and a 'total B' column are arranged. <P>COPYRIGHT: (C)2003,JPO | ||||||
| 143 | Device, and method for processing functional block diagram, and program | JP2009089759 | 2009-04-02 | JP2010244157A | 2010-10-28 | KANBARA ICHIRO; MURAKAMI HITOSHI; SATO SUSUMU; KODAMA TOSHIHIDE |
| PROBLEM TO BE SOLVED: To provide a functional block diagram processing device, a functional block diagram processing method and a program for detecting the difference of the addresses of data. SOLUTION: A functional block diagram processing device includes: a storage part for storing a plurality of pieces of functional block information showing the functional block of a computer program, the functional block information having a block identifier for identifying a functional block and a data identifier for identifying data to be processed by the functional block; a relativization processing part for performing the relativization processing of an address shown by the data identifier included in each of the plurality of pieces of functional block information; a comparison part for comparing the plurality of pieces of functional block information subjected to relativization processing; and a display part for displaying the result of comparison. COPYRIGHT: (C)2011,JPO&INPIT | ||||||
| 144 | Device for analyzing vector variable block diagram | JP27367598 | 1998-09-28 | JP2000105760A | 2000-04-11 | TANUMA MASAYA |
| PROBLEM TO BE SOLVED: To make stably and quickly performable the time response calculation of a vector variable block diagram. SOLUTION: The device for analyzing a vector variable block diagram is provided with a terminal means 2 having an input part and a display part and a calculating means 1 for performing input and output processing between it and the terminal means 2. The calculating means 1 is provided with a time response calculating part 8 for performing calculation by virtually inserting a sample holder between a scalar variable part and a vector variable part. Moreover, the calculating means 1 is provided with a block diagram data inputting part 3, pre-processing part 4 before time response calculation, calculation model for vector variable model generating part 5, input variable calculating part 6, calculation model for scalar variable model generating part 7, and output processing part 9. COPYRIGHT: (C)2000,JPO | ||||||
| 145 | Image display system of block diagram for defective part | JP13683288 | 1988-06-03 | JPH01305382A | 1989-12-08 | KAWAGUCHI MASAAKI |
| PURPOSE: To monitor faults in many components with a small-scale apparatus by updating surface images even if a component corresponding to fault data are not displayed, and performing the display to which a significance is imparted corresponding to the content of the fault of said component. CONSTITUTION: At first, a central processing unit 21 forms image source information, fault information, etc., in accordance with a batch processing program beforehand. They are stored in an image source information file 4, a fault information file 5 and an image display information file 6. When, the fault data for every component are supplied from a radar system in on-line state, the data are aligned and stored in a fault data file 1. Then, a monitoring person operates a keyboard 3 and selects the image. The file matching the kind of the specified image is read out of the file 6 and displayed on a graphic display 7. The displayed fault data are read out of the file 1, and the significance of the content of the fault is imparted to the component on the displayed image in correspondence with the fault data. When a specified indication, e.g., a color, is applied for every content to which the significance is imparted, the location of the fault can be determined. COPYRIGHT: (C)1989,JPO&Japio | ||||||
| 146 | Screen display system for direct digital control block diagram | JP26825287 | 1987-10-26 | JPH01111209A | 1989-04-27 | SAKAGUCHI KAZUO |
| PURPOSE:To quickly identify a reversed area by deleting the arithmetic order identification numbers out of a screen and using different colors or different degrees of luminance to connection lines and arrows for distinction between the forward and reverse arithmetic orders. CONSTITUTION:In case the arithmetic is not carried out in the prescribed order, i.e., the arithmetic order is not coincident with the directions of arrows 14 added to the connection lines 12 and 13, the arithmetic order is reversed between an input/output signal block 11 shown by LA100, for example, and a control block 10 shown by PI. In such a case,the colors and/or degrees of luminance of the connection line 12 and/or arrows are different from those of other connection lines 13 and arrows 14 for emphasized display. Thus it is possible to obviously know that the block 11 shown by LA100 is calculated after calculation of the block 10 shown by PI. | ||||||
| 147 | Block diagram type simulator system oriented to process control system | JP6026185 | 1985-03-25 | JPS61220061A | 1986-09-30 | IMAI TAKAO; SAITO YOSHIKUNI; OZAWA JUNICHIRO |
| PURPOSE: To easily change and control objects of simulation by inputting the block diagram of a process control system to a graphic display and then plotting drawing and editing it, and analyzing the block diagram. CONSTITUTION: An input signal from an input device 12 is imagewise processed by an input processing part 7 and a block diagram input and editing part 1 displays the block diagram on a display according to both data in a block control information file 8 and a user block storage file 9; and the block diagram is edited over a direct look at it and a completed block diagram is stored in the file 9. Data on the block diagram completed at the editing part 1 are checked by a block diagram analyzing part 2 and converted into information showing which block is analyzed for simulation SML to begin with, and the information is stored in an SML information file 10. Then, data for the SML is inputted to on a keyboard, a parameter setting part 6 for SML transfers the data to an SML execution part 3 to carry out the SML, and the result is stored in a file 11. COPYRIGHT: (C)1986,JPO&Japio | ||||||
| 148 | GRAPHICAL PROGRAMMING SYSTEM WITH DISTRIBUTED BLOCK DIAGRAM EXECUTION AND USER INTERFACE DISPLAY | EP00957450.0 | 2000-08-15 | EP1216441B1 | 2015-05-27 | DYE, Robert, E.; SHAH, Darshan; ROGERS, Steve; RICHARDSON, Greg; LUICK, Dean, A. |
| System and method for executing a graphical program on a first computer and providing a user interface of the graphical program on a second computer, where the graphical program includes a plurality of interconnected function icons representing graphical data flow of a function. Information indicating a plurality of graphical programs on the first computer, e.g., a list, may be displayed on the second computer, and user input specifying the graphical program on the first computer received to the second computer, e.g., selecting the graphical program from the list of graphical programs. The graphical program is executed on the first computer, and information describing the user interface of the graphical program is provided to the second computer during execution. The user interface of the graphical program is displayed on the second computer, facilitating interaction between a user of the second computer and the graphical program executing on the first computer. | ||||||
| 149 | MODE-SWITCHED VARIABLE SIGNAL ATTRIBUTES IN BLOCK DIAGRAMS | PCT/US2008/080119 | 2008-10-16 | WO2009052257A1 | 2009-04-23 | CHUTINAN, Alongkrit; MANI, Ramamurthy; JIA, Dong; FENG, Haihua; ZHANG, Qu; RAGHAVAN, Vijay |
A programming element is provided that defines model attributes in response to mode change events in a graphical modeling environment. Such definition may involve any signal attribute such as dimensions, data types, complexity and sample times. Events that trigger definition of model attributes may be explicit signaling events generated by other elements, elements within the block diagram programming environment, and elements external from the environment. Implicit events may also trigger definition of model attributes, such as a change of attribute in an input signal. |
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| 150 | MESSGERÄT MIT ÜBER EIN BLOCKDIAGRAMM ANSTEUERBAREN FUNKTIONSEINHEITEN | PCT/EP2002/004762 | 2002-04-30 | WO2002095426A1 | 2002-11-28 | PAULY, Andreas; BRAUNSTORFINGER, Thomas; KERNCHEN, Wolfgang; DESQUIOTZ, René |
Ein Messgerät, insbesondere ein Signalgenerator (1), hat mehrere Funktionseinheiten (2a, 2b, 13a, 13b...), die miteinander variabel verschaltbar sind, eine Steuereinrichtung (28), die die Verschaltung und die Funktionen der Funktionseinheiten (2a, 2b, 13a, 13b...) festlegt, und eine optische Darstellungseinrichtung (29). Die Funktionseinheiten (2a, 2b, 13a, 13b...) sind durch Funktionsblöcke (102, 102b, 113a, 113b,...) symbolisiert, die auf der Darstellungseinrichtung (29) darstellbar sind und mit Verbindungselementen (140-147) graphisch verbindbar sind. Die Steuereinrichtung (28) steuert die Darstellungseinrichtung (29) so an, dass die Funktionsblöcke (102, 102b, 113a, 113b,...) entsprechend der aktuellen Verschaltung der Funktionseinheiten (2a, 2b, 13a, 13b...) über die Verbindungselemente (140-147) graphisch miteinander verbunden sind. |
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| 151 | Circuit block diagram creation device, circuit block diagram creation method, and method for manufacturing semiconductor integrated circuit | JP2009211786 | 2009-09-14 | JP2011060188A | 2011-03-24 | TSUKAMOTO YASUTAKA |
| <P>PROBLEM TO BE SOLVED: To facilitate changes, such as hierarchical movement of a RAM and a change from non-sharing to sharing of a RAM or a change from sharing to non-sharing of a RAM in LSI design, and to reduce the design man-hours and design mistakes. <P>SOLUTION: A circuit block diagram creation device includes a RAM selection means (12) for determining the selection of a RAM for sharing from data of RAMs disposed in a circuit block; a RAM moving means (13) for moving the data of the RAM whose selection has been confirmed to another block; a RAM interface circuit creation means (14) for automatically creating a RAM interface circuit required according to the movement of the RAM data; and circuit description source code creation means (15) for automatically creating a circuit description source code (16) in which the operation of the circuit is described. <P>COPYRIGHT: (C)2011,JPO&INPIT | ||||||
| 152 | VERFAHREN UND ANORDNUNG ZUR BESTIMMUNG EINES RAUCHBEGRENZUNGSKENNFELDES EINES VERBRENNUNGSMOTORS | PCT/EP2011/069134 | 2011-10-31 | WO2012076256A1 | 2012-06-14 | VÖGL, Rainer; VOGELS, Marie-Sophie; DAUM, Steffen; ERHART, Josef |
Die Erstellung eines Rauchbegrenzungskennfeldes ist ein aufwendiger Vorgang, der hochqualifiziertes und hocherfahrenes Fachwissen erfordert. Um den Aufwand für die Erstellung zu reduzieren wird erfindungsgemäß vorgeschlagen, für eine Anzahl von Drehzahlen jeweils eine Anzahl von Lastsprüngen durchzuführen und dabei die Opazität O zu messen und mit einer Opazitätsgrenze Olimit zu vergleichen, wobei für jede Drehzahl n mit einem vorgegebenen minimalen Verbrennungsluftverhältnis λmin begonnen wird und jeder Lastsprung unter jeweiliger Erhöhung des jeweils letzten Verbrennungsluftverhältnisses λ um ein Verbrennungsluftverhältnisinkrement λinc solange wiederholt wird, bis die gemessene Opazität O unter einer vorgegebenen Opazitätsgrenze Olimit liegt. |
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| 153 | KOMBINIERTE BLOCK- UND INDIVIDUALANTRIEBSVORRICHTUNG, INSBESONDERE FÜR PIPETTIERKANÄLE | PCT/EP2013/068990 | 2013-09-13 | WO2014041113A1 | 2014-03-20 | NAWROCKI, Eduard |
Die vorliegende Erfindung betrifft eine kombinierte Block- und Individualantriebsvorrichtung, welche dazu ausgebildet ist, eine Mehrzahl von Bewegungsobjekten (14a-14h), sowohl als Block gemeinsam längs einer Bewegungsbahn (B), als auch mit einem vorgegebenen Relativbewegungsmuster relativ zueinander längs der Bewegungsbahn (B) zu bewegen. Die Erfindung ist dadurch gekennzeichnet, dass an wenigstens einem Teil der Bewegungsobjekte (14a-14h) wenigstens eine Spindelmutter (58b-58h) des Bewegungsobjekts (14b-14h) relativ zu diesem um eine Antriebsspindellängsachse (ASL) drehbar aufgenommen ist, sowie dadurch, dass ein Relativbewegungsübertragungsgetriebe (40) eine Antriebswelle (44) mit zur Antriebsspindellängsachse (ASL) paralleler Antriebswellenlängsachse (ASL) und an jedem Bewegungsobjekt mit relativ zu diesem um die Antriebsspindellängsachse (ASL) drehbarer Spindelmutter (58b-58h) einen gemeinsam mit dem Bewegungsobjekt (14b-14h) relativ zur Antriebswelle (44) längs der Antriebswellenlängsachse (ASL) beweglichen und gemeinsam mit der Antriebswelle (44) drehbaren Gleitstein (60b-60h) aufweist, wobei die Spin- delmutter (58b-58h) durch Rotation der Antriebswelle (44) um die Antriebswellenlängsachse (AWL) unter Bewegungsvermittlung des Gleitsteins (60b- 60h) zur Drehung um die Antriebsspindellängsachse (ASL) antreibbar ist, und bei Drehung der Antriebsspindel (40) in Umfangsrichtung um die Antriebsspindellängsachse (ASL) durch den Gleitstein (60b-60h) an der Antriebswelle (44) abgestützt ist. |
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| 154 | ブロック線図処理装置およびブロック線図の処理方法 | JP2011229113 | 2011-10-18 | JP5755103B2 | 2015-07-29 | 山口 朗 |
| 155 | Program generation device and block diagram generation device | JP2009048455 | 2009-03-02 | JP2010204855A | 2010-09-16 | ISHII ENA; YOSHIDA MITSUNOBU |
| PROBLEM TO BE SOLVED: To provide a program generation device and a block diagram generation device, for generating a program so as not to unnecessarily increasing the number of program instructions even in the case of a block diagram having a multiple branch, and maintaining original visual representation of the block diagram as a figure for restoration. SOLUTION: The program generation device includes: a means reading a block diagram having at least two branch points; a means dividing the block diagram at each branch point to generate a plurality of block diagram pieces; a means generating structure information of the plurality of block diagram pieces; a means generating program instructions for processing a plurality of first block diagram pieces; and a program generation means arranging each program instruction, describing the structure information of each first block diagram piece in a comment line of the program instruction corresponding to each first block diagram piece, and describing the structure information of a second block diagram piece in any comment line of the program instructions to generate the program. COPYRIGHT: (C)2010,JPO&INPIT | ||||||
| 156 | Program generating device and block diagram generating apparatus | JP2008021342 | 2008-01-31 | JP2009181446A | 2009-08-13 | ISHII ENA; YOSHIDA MITSUNOBU |
| <P>PROBLEM TO BE SOLVED: To restore a block diagram from a program (source code), and to associate each instruction in the source code and each section of the block diagram. <P>SOLUTION: A program generating device includes: a block diagram division means for dividing a block diagram into plurality by branch points, and for connecting the branch block elements to one ends of data lines connected to the branch points in each division piece to generate a plurality of block diagram pieces; a program instruction generation means for generating a program instruction to achieve the processing of each block diagram piece; a performance sequence determination means for determining the performance sequence of each program instruction; a structure information generation means for generating the structure information of the block diagram piece for each block diagram piece; and a program generation means for arranging each program instruction according to the sequence of performance, and for describing the structure information of each block diagram piece in a comment line corresponding to each program instruction to generate a program. <P>COPYRIGHT: (C)2009,JPO&INPIT | ||||||
| 157 | Method and device for partially analyzing block diagram | JP1779196 | 1996-02-02 | JPH09212232A | 1997-08-15 | TANUMA MASAYA |
| PROBLEM TO BE SOLVED: To provide a block diagram analyzing method and its device capable of optionally generating and analyzing various sub-models from one original block diagram in accordance with a user's request and easily controlling and analyzing a large scale model. SOLUTION: This partial analysis method has a display means 11 and an arithmetic means 12, and the means 12 executes analysis by using an analyzer consisting of a block diagram data input part 13, an input part 14 for a variable to be analyzed, an automatic generation part 15 for a partial block diagram, a time response calculating part 16 and a calculated result output part 17. Namely one or more dynamic operation elements to be analyzed are specified, algebraic elements on a route between the specified dynamic operation elements, algebraic elements on the specified dynamic operation element and another dynamic operation element, or algebraic elements on a route between the specified dynamic operation element and an external input are extracted to prepare a partial block diagram and the time response of the partial block diagram is calcuated, so that the time response analysis of an optional element can be executed without changing the initially prepared block diagram data. | ||||||
| 158 | Automatic program generating device with block diagram processing function | JP21671590 | 1990-08-17 | JPH0498531A | 1992-03-31 | SANO YASUKO |
| PURPOSE: To extremely improve the working efficiency for generation of a program by providing a program generating means, a block diagram program generating means, and a variable attribute control means. CONSTITUTION: A block diagram program generating means 4 analyzes the contents shown by the block diagram form system specifications 7 in accordance with the program generation goal received from a program generation control means 12. Then the means 4 decides the name of the variable to be used in a part program that is generated thereafter so that the same name is given to the variable having the same meaning as the variable that is used in another part program after generating a variable attribute deciding pattern based on an internal knowledge base of its own and sending the pattern to a variable attribute control means 5. Thus a desired part program is obtained. As a result, the reduction of labor and the working efficiency can be more improved for generation of a program. COPYRIGHT: (C)1992,JPO&Japio | ||||||
| 159 | Graphical program execution with distributed block diagram display | US12143198 | 2008-06-20 | US08074203B2 | 2011-12-06 | Robert E. Dye; Darshan Shah; Steve Rogers; Greg Richardson; Dean A. Luick |
| System and method for executing a graphical program on a first computer and providing a user interface of the graphical program on a second computer, where the graphical program includes a plurality of interconnected function icons representing graphical data flow of a function. Information indicating a plurality of graphical programs on the first computer, e.g., a list, may be displayed on the second computer, and user input specifying the graphical program on the first computer received to the second computer, e.g., selecting the graphical program from the list of graphical programs. The graphical program is executed on the first computer, and information describing the user interface of the graphical program is provided to the second computer during execution. The user interface of the graphical program is displayed on the second computer, facilitating interaction between a user of the second computer and the graphical program executing on the first computer. | ||||||
| 160 | GRAPHICAL PARTITIONING FOR PARALLEL EXECUTION OF EXECUTABLE BLOCK DIAGRAM MODELS | US12895209 | 2010-09-30 | US20110078652A1 | 2011-03-31 | Ramamurthy MANI; Katalin Maria POPOVICI; Hidayet Tunc SIMSEK; Benjamin Charles MARTIN; John Edward CIOLFI |
| Exemplary embodiments allow executable graphical models, such as block diagram models, to be graphically partitioned for execution on concurrent computing resources. Embodiments allow model components to be grouped into subtasks that are affiliated with tasks associated with concurrent computing resources. Tasks and sub graphs can be mapped to concurrent computing resources according to characteristics, such as sample time, solver type, etc. Embodiments further allow mappings to be visually indicated to a user via various display techniques including color, text, icons, shading, grouping of identifiers, etc. Concurrently executing portions of a model allows model results to be obtained faster than can be obtained when models are executed on a single computing resource, such as a single processor. | ||||||
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