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Binnig
Carsten Binnig, Elztal DE
| Patent application number | Description | Published |
|---|---|---|
| 20100328115 | DICTIONARY-BASED ORDER-PRESERVING STRING COMPRESSION FOR MAIN MEMORY COLUMN STORES - Methods and systems are described that involve usage of dictionaries for compressing a large set of variable-length string values with fixed-length integer keys in column stores. The dictionary supports updates (e.g., inserts of new string values) without changing codes for existing values. Furthermore, a shared-leaves approach is described for indexing such a dictionary that compresses the dictionary itself while offering access paths for encoding and decoding. | 12-30-2010 |
Gerd Binnig, Kottgeisering DE
| Patent application number | Description | Published |
|---|---|---|
| 20080292153 | Generating an anatomical model using a rule-based segmentation and classification process - A system for computer-aided detection uses a computer-implemented network structure to analyze patterns present in digital image slices of a human body and to generate a three-dimensional anatomical model of a patient. The anatomical model is generated by detecting easily identifiable organs first and then using those organs as context objects to detect other organs. A user specifies membership functions that define which objects of the network structure belong to the various classes of human organs specified in a class hierarchy. A membership function of a potentially matching class determines whether a candidate object of the network structure belongs to the potential class based on the relation between a property of the voxels linked to the candidate object and a property of the context object. Some voxel properties used to classify an object are location, brightness and volume. The human organs are then measured to assist in the patient's diagnosis. | 11-27-2008 |
| 20100265267 | Analyzing pixel data by imprinting objects of a computer-implemented network structure into other objects - An analysis system analyzes digital images using a computer-implemented network structure that includes a process hierarchy, a class network and a data network. The data network includes image layers and object networks. Objects in a first object network are segmented into a first class, and objects in a second object network are segmented into a second class. One process step of the process hierarchy involves generating a third object network by imprinting objects of the first object network into the objects of the second object network such that pixel locations are unlinked from objects of the second object network to the extent that the pixel locations were also linked to objects of the first object network. The imprinting step allows object-oriented processing of digital images to be performed with fewer computations and less memory. Characteristics of an object of the third object network are then determined by measuring the object. | 10-21-2010 |
| 20110122138 | Context driven image mining to generate image-based biomarkers - An image-based biomarker is generated using image features obtained through object-oriented image analysis of medical images. The values of a first subset of image features are measured and weighted. The weighted values of the image features are summed to calculate the magnitude of a first image-based biomarker. The magnitude of the biomarker for each patient is correlated with a clinical endpoint, such as a survival time, that was observed for the patient whose medical images were analyzed. The correlation is displayed on a graphical user interface as a scatter plot. A second subset of image features is selected that belong to a second image-based biomarker such that the magnitudes of the second image-based biomarker for the patients better correlate with the clinical endpoints observed for those patients. The second biomarker can then be used to predict the clinical endpoint of other patients whose clinical endpoints have not yet been observed. | 05-26-2011 |
Gerd Binnig, Wollerau CH
| Patent application number | Description | Published |
|---|---|---|
| 20090003189 | PROBE FOR SCANNING OVER A SUBSTRATE AND A DATA STORAGE DEVICE - A method of scanning over a substrate includes implementing a write mode of the substrate by scanning a probe across a substrate, the probe having a spring cantilever probe mechanically fixed to a probe holding structure, a tip with a nanoscale apex, and an actuator for lateral positioning of the tip; the actuator comprising a thermally switchable element and a heating element for heating the thermally switchable element; and heating the heating element to a given temperature so as to locally soften a portion of the substrate and applying a force to the softened portion of the substrate through the tip so as to create one or more indentation marks in the softened portion of the substrate. | 01-01-2009 |
Gerd K. Binnig, Wollerau CH
| Patent application number | Description | Published |
|---|---|---|
| 20080225676 | Data storage device and control - The present invention provides data storage devices, systems and methods. An example device includes: a storage medium for storing data in the form of marks; and at least one probe. The probe(s) and storage medium are operable to move relative to each other, with each probe comprising a tip facing the storage medium and having a force creating unit associated thereto. The force creating units are operable to create a force acting between the tip and said storage medium. The data storage device is operable to erase an indentation mark in the storage medium by way of controlling the force creating unit for creating at least one erase force pulse with a force rise time being less than or equal to the order of 1 microsecond. | 09-18-2008 |
| 20080230696 | SURFACE TREATMENT AND SURFACE SCANNING - Provides surface treatment devices, surface scanning devices, methods of operating a surface treatment device and methods of operating a surface scanning device. An area within a medium comprises at least one sharpening location for sharpening a tip of a probe mechanically. The tip is conically shaped with a radius of an apex smaller than 100 nm. In the case of the surface treatment device the probe is designed for altering the surface of the medium. In the case of the surface scanning device the probe is designed for scanning the medium. The sharpening location is suited for sharpening the tip mechanically. For that purpose the probe and the medium are being moved relative to each other such that the tip is located in the sharpening location. Then the probe and/or the medium are moved relative to each other such, that the tip is mechanically sharpened. | 09-25-2008 |
| 20080247300 | STORAGE DEVICE AND METHOD FOR SCANNING A STORAGE MEDIUM - A storage device and a method for scanning a storage medium. A storage medium for storing data in the form of marks is scanned by an array of probes for mark detecting purposes in a scanning mode. The storage medium has fields with each field to be scanned by an associated one of the probes. At least one of the fields has marks representing operational data for operating the scanning mode. Scanning parameters are computed from the operational data and the scanning mode is adjusted according to the computed parameters. | 10-09-2008 |
| 20080271522 | SAMPLE ANALYSIS USING CANTILEVER PROBE - A method and apparatus for analysis of a sample. The method includes an accessing operation for accessing a region of the sample via a tip of at least one probe mounted on a cantilever. A removing operation removes a sample material from the region that is accessed by the tip of the at least one probe mounted on the cantilever. A sensing operation senses a parameter associated to the removal of the sample material in the removing operation. The accessing, removing, and sensing operations are repeated to facilitate removal of at least one layer of the sample. | 11-06-2008 |
| 20080316905 | Data Storage Device - A storage device including a storage medium for storing data in the form of topographic or magnetic marks. At least one probe is mounted on a common frame, the common frame and the storage medium designed for moving relative to each other for creating or detecting said marks. Each probe includes a tip facing the storage medium, a read sensing element, a write element and a capacitive platform, that forms a first electrode and is designed for a voltage potential applied to it independent from a control signal for said read sensing element and for said voltage potential applied to said capacitive platform being independent from a control signal for said write heating element. It further comprises a second electrode arranged in a fixed position relative to the storage medium forming a first capacitor together wherein said first electrode and a medium between the first and second electrode. | 12-25-2008 |