A-Coord input: augmented pen-based interactions by combining auxiliary input channels

Hasan, Mohammad Khalad

10 April 2012

Pen-based interactions are becoming widely popular on a variety of devices, including tabletPCs, mobile devices and tabletop systems. The digital pens and tablets have evolved considerably and served users in creative industries. A digital pen can sense various auxiliary inputs, such as tilt, pressure and roll. Researchers have explored properties of each channel in isolation of another. Since the human wrist and fingers can operate multiple input channels simultaneously, a natural progression warrants examination of controllability when these channels are operated simultaneously. In this thesis, I explore a class of interaction techniques, a-coord input, which requires users to control two auxiliary channels simultaneously. Through experiments, I explore the design space of a-coord input and investigate the effect of changing the order in which the channels are combined. Furthermore, I investigate its effectiveness for discrete and continuous selection tasks. Finally, this thesis shows the value of a-coord input through several applications.

Pen-based Interaction

Dual-channel input

Pen Roll

Pen Pressure

Pen Tilt

I det fria ordets lag : En studie i fristadsprogrammets verksamhet och funktion

Söderbaum, Fredrik

January 2015

No description available.

Fristadsprogrammet

Exil

ICORN

PEN

A-Coord input: augmented pen-based interactions by combining auxiliary input channels

Hasan, Mohammad Khalad

10 April 2012

Pen-based interactions are becoming widely popular on a variety of devices, including tabletPCs, mobile devices and tabletop systems. The digital pens and tablets have evolved considerably and served users in creative industries. A digital pen can sense various auxiliary inputs, such as tilt, pressure and roll. Researchers have explored properties of each channel in isolation of another. Since the human wrist and fingers can operate multiple input channels simultaneously, a natural progression warrants examination of controllability when these channels are operated simultaneously. In this thesis, I explore a class of interaction techniques, a-coord input, which requires users to control two auxiliary channels simultaneously. Through experiments, I explore the design space of a-coord input and investigate the effect of changing the order in which the channels are combined. Furthermore, I investigate its effectiveness for discrete and continuous selection tasks. Finally, this thesis shows the value of a-coord input through several applications.

Pen-based Interaction

Dual-channel input

Pen Roll

Pen Pressure

Pen Tilt

Image-based pen-and-ink illustration /

Salisbury, Michael P.,

January 1997

Thesis (Ph. D.)--University of Washington, 1997. / Vita. Includes bibliographical references (p. [116]-119).

Computer graphics. Pen drawing

A Feasibility Evaluation of a Digital Pen and Paper System for Accomplishing Electronic Anesthesia Record-keeping

Piotrowski, Kathleen Ann

January 2011

In 2001, the Institute of Medicine stated that one of the parameters needing to be addressed to improve health care was the creation of electronic health records for all patients. This goal has proven to be very challenging to health care providers. Many barriers exist that prevent the goal of computerizing health records such as high costs, usability problems, interface incompatibility, and fear of change. The purpose of this feasibility project was to evaluate the usefulness and acceptability of a digital pen and paper (DPP) system for anesthesia documentation. The specific DPP technology used in this evaluation was a product developed by Shareable Ink®. Seven certified registered nurse anesthetists (CRNAs) evaluated the DPP system through a cognitive walkthrough procedure. During the cognitive walkthrough, the participants talked aloud as they carried out a series of anesthesia documentation tasks. Just prior to the cognitive walkthrough, participants were given a questionnaire that measured their perceived computer knowledge, attitudes and skills. After the cognitive walkthrough, a second questionnaire was used to determine their satisfaction with the DPP and their opinions about its usefulness for use in multiple anesthesia work settings. In the second phase of the project, I interviewed other stakeholders in the hospital environment who would also be affected by implementation of a DPP system. This portion of the study was conducted at a community hospital without electronic record-keeping capability. Participation from several departments was sought via contact with hospital administration and department heads. Among those departments targeted for interviews were: Information Technology, Chief of Anesthesia, Anesthesia Billing, Medical Records and Nursing. Semi- structured interviews were conducted and the responses of the participants recorded both as field notes and via audio recording. This intent of this study was to test the feasibility of the digital pen and paper system for various types of anesthesia work environments by means of descriptive, survey and qualitative data analysis. Overall, the device was not only found to be usable by providers but also acceptable to stakeholders. Therefore, this device could be deemed a feasible solution toward implementing and adopting electronic documentation in some anesthesia work settings.

Digital pen

Nursing

Anesthesia

Computer

Pressure-sensitive Pen Interactions

Ramos, Gonzalo

28 July 2008

Pen-based computers bring the promise of tapping into people’s expressiveness with pen and paper and producing a platform that feels familiar while providing new functionalities only possible within an electronic medium. To this day, pen computers’ success is marginal because their interfaces mainly replicate keyboard and mouse ones. Maximizing the potential of pen computers requires redesigning their interfaces so that they are sensitive to the pen’s input modalities and expressiveness. In particular, pressure is an important and expressive, yet underutilized, pen input modality. This dissertation advances our knowledge about pressure-aware, pen-based interactions and how people use these techniques. We systematically explore their design by first investigating how pressure can affect pen interactions. We propose novel techniques that take advantage of the pressure modality of a pen to control, link, and annotate digital video. We then study people’s performance using pressure to navigate through a set of elements and find that they can discriminate a minimum of six different pressure regions. We introduce the concept of Pressure Widgets and suggest visual and interaction properties for their design. We later explore pressure’s use to enhance the adjustment of continuous parameters and propose Zliding, a technique in which users vary pressure to adjust the scale of the parameter space, while sliding their pen to perform parameter manipulations. We study Zliding and find it a viable technique, which is capable of enabling arbitrarily precise parameter adjustments. We finally present a novel interaction technique defined by the concurrent variation in pressure applied while dragging a pen. We study these pressure marks and find that they are a compact, orientation-independent, full interaction phrase that can be 30% faster than a stateof-the-art selection-action interaction phrase. This dissertation also makes a number of key contributions throughout the design and study of novel interaction techniques: -It identifies important design issues for the development of pressure-sensitive, pen operated widgets and interactions, -It provides design guidelines for interaction techniques and interface elements utilizing pressure-enabled input devices, -It presents empirical data on people’s ability to control pressure, and -It charts a visual design space of pressure-sensitive, pen-based interactions.

HCI

Pressure

Pen

Interfaces

0984

Pressure-sensitive Pen Interactions

Ramos, Gonzalo

28 July 2008

Pen-based computers bring the promise of tapping into people’s expressiveness with pen and paper and producing a platform that feels familiar while providing new functionalities only possible within an electronic medium. To this day, pen computers’ success is marginal because their interfaces mainly replicate keyboard and mouse ones. Maximizing the potential of pen computers requires redesigning their interfaces so that they are sensitive to the pen’s input modalities and expressiveness. In particular, pressure is an important and expressive, yet underutilized, pen input modality. This dissertation advances our knowledge about pressure-aware, pen-based interactions and how people use these techniques. We systematically explore their design by first investigating how pressure can affect pen interactions. We propose novel techniques that take advantage of the pressure modality of a pen to control, link, and annotate digital video. We then study people’s performance using pressure to navigate through a set of elements and find that they can discriminate a minimum of six different pressure regions. We introduce the concept of Pressure Widgets and suggest visual and interaction properties for their design. We later explore pressure’s use to enhance the adjustment of continuous parameters and propose Zliding, a technique in which users vary pressure to adjust the scale of the parameter space, while sliding their pen to perform parameter manipulations. We study Zliding and find it a viable technique, which is capable of enabling arbitrarily precise parameter adjustments. We finally present a novel interaction technique defined by the concurrent variation in pressure applied while dragging a pen. We study these pressure marks and find that they are a compact, orientation-independent, full interaction phrase that can be 30% faster than a stateof-the-art selection-action interaction phrase. This dissertation also makes a number of key contributions throughout the design and study of novel interaction techniques: -It identifies important design issues for the development of pressure-sensitive, pen operated widgets and interactions, -It provides design guidelines for interaction techniques and interface elements utilizing pressure-enabled input devices, -It presents empirical data on people’s ability to control pressure, and -It charts a visual design space of pressure-sensitive, pen-based interactions.

HCI

Pressure

Pen

Interfaces

0984

Development of a microfluidic device for patterning multiple species by scanning probe lithography

Rivas Cardona, Juan Alberto

02 June 2009

Scanning Probe Lithography (SPL) is a versatile nanofabrication platform that leverages microfluidic “ink” delivery systems with Scanning Probe Microscopy (SPM) for generating surface-patterned chemical functionality on the sub-100 nm length scale. One of the prolific SPL techniques is Dip Pen Nanolithography™ (DPN™). High resolution, multiplexed registration and parallel direct-write capabilities make DPN (and other SPL techniques) a power tool for applications that are envisioned in micro/nano-electronics, molecular electronics, catalysis, cryptography (brand protection), combinatorial synthesis (nano-materials discovery and characterization), biological recognition, genomics, and proteomics. One of the greatest challenges for the successful performance of the DPN process is the delivery of multiple inks to the scanning probe tips for nano-patterning. The purpose of the present work is to fabricate a microfluidic ink delivery device (called “Centiwell”) for DPN (and other SPL) applications. The device described in this study maximizes the number of chemical species (inks) for nanofabrication that can be patterned simultaneously by DPN to conform the industrial standards for fluid handling for biochemical assays (e.g., genomic and proteomic). Alternate applications of Centiwell are also feasible for the various envisioned applications of DPN (and other SPL techniques) that were listed above. The Centiwell consists of a two-dimensional array of 96 microwells that are bulk micromachined on a silicon substrate. A thermoelectric module is attached to the back side of the silicon substrate and is used to cool the silicon substrate to temperatures below the dew point. By reducing the temperature of the substrate to below the dew point, water droplets are condensed in the microwell array. Microbeads of a hygroscopic material (e.g., poly-ethylene glycol) are dispensed into the microwells to prevent evaporation of the condensed water. Furthermore, since poly-ethylene glycol (PEG) is water soluble, it forms a solution inside the microwells which is subsequently used as the ink for the DPN process. The delivery of the ink to the scanning probe tip is performed by dipping the tip (or multiple tips in an array) into the microwells containing the PEG solution. This thesis describes the various development steps for the Centiwell. These steps include the mask design, the bulk micromachining processes explored for the micro-fabrication of the microwell array, the thermal design calculations performed for the selection of the commercially available thermoelectric coolers, the techniques explored for the synthesis of the PEG microbeads, and the assembly of all the components for integration into a functional Centiwell. Finally, the successful implementation of the Centiwell for nanolithography of PEG solutions is also demonstrated.

microfluidic device

Dip-Pen Nanolithography

Erfahrungen mit einem C-Pen

Ziegler, Christoph

02 September 2002

Gemeinsamer Workshop von Universitaetsrechenzentrum und Professur Rechnernetze und verteilte Systeme der Fakultaet fuer Informatik der TU Chemnitz. Der Vortrag beginnt mit der Vorstellung eines C-Pen. Erfahrungen mit der praktischen Anwendung eines solchen "Computer-Stiftes" bilden den Hauptteil.

C-Pen

ddc:004

Scanner

The evolution of a corporate public relations function Parker Pen Company, 1946-1966 /

Sullivan, Robert Arthur,

January 1967

Thesis (M.S.)--University of Wisconsin--Madison, 1967. / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Parker Pen Company. Public relations.