81 research outputs found
Review of Display Technologies Focusing on Power Consumption
Producción CientíficaThis paper provides an overview of the main manufacturing technologies of
displays, focusing on those with low and ultra-low levels of power consumption, which
make them suitable for current societal needs. Considering the typified value obtained from
the manufacturer’s specifications, four technologies—Liquid Crystal Displays, electronic
paper, Organic Light-Emitting Display and Electroluminescent Displays—were selected in
a first iteration. For each of them, several features, including size and brightness, were
assessed in order to ascertain possible proportional relationships with the rate of
consumption. To normalize the comparison between different display types, relative units
such as the surface power density and the display frontal intensity efficiency were
proposed. Organic light-emitting display had the best results in terms of power density for
small display sizes. For larger sizes, it performs less satisfactorily than Liquid Crystal
Displays in terms of energy efficiency.Junta de Castilla y León (Programa de apoyo a proyectos de investigación-Ref. VA036U14)Junta de Castilla y León (programa de apoyo a proyectos de investigación - Ref. VA013A12-2)Ministerio de Economía, Industria y Competitividad (Grant DPI2014-56500-R
OLED microdisplays for augmented reality applications
Microdisplays are widely used in head mounted displays (HMDs), electronic viewfinders (EVF) and
other near-to-the-eye visualization systems. Due to their superior image quality, power efficiency and compactness, emissive type microdisplays based on OLEDs have been strongly increasing their market share for these applications. With the potential and recent advances of wearable Augmented Reality (AR), OLED microdisplays start to enter this application
Optogenetic stimulation probes with single-neuron resolution based on organic LEDs monolithically integrated on CMOS
Funding: This work was supported in part by the Defense Advanced Research Projects Agency (DARPA) under contract N6600117C4012, by the National Institutes of Health under grant U01NS090596, by the Leverhulme Trust (RPG-2017-231) and by the Alexander von Humboldt Stiftung (Humboldt-Professorship to M.C.G.). This work was performed in part at the Columbia Nano Initiative cleanroom facility, at the CUNY Advanced Science Research Center Nanofabrication Facility, and at the Singh Center for Nanotechnology, part of the National Nanotechnology Coordinated Infrastructure Program, which is supported by the National Science Foundation grant NNCI-2025608. C.-K.M. acknowledges funding from the European Commission through a Marie-Skłodowska Curie Individual Fellowship (101029807).The use of optogenetic stimulation to evoke neuronal activity in targeted neural populations—enabled by opsins with fast kinetics, high sensitivity and cell-type and subcellular specificity—is a powerful tool in neuroscience. However, to interface with the opsins, deep-brain light delivery systems are required that match the scale of the spatial and temporal control offered by the molecular actuators. Here we show that organic light-emitting diodes can be combined with complementary metal–oxide–semiconductor technology to create bright, actively multiplexed emissive elements. We create implantable shanks in which 1,024 individually addressable organic light-emitting diode pixels with a 24.5 µm pitch are integrated with active complementary metal–oxide–semiconductor drive and control circuitry. This integration is enabled by controlled electrode conditioning, monolithic deposition of the organic light-emitting diodes and optimized thin-film encapsulation. The resulting probes can be used to access brain regions as deep as 5 mm and selectively activate individual neurons with millisecond-level precision in mice.Publisher PDFPeer reviewe
High-density integration of ultrabright OLEDs on a miniaturized needle-shaped CMOS backplane
This work was supported in part by the Defense Advanced Research Projects Agency (DARPA) under Contract N6600117C4012, by the National Institutes of Health under Grant U01NS090596, and by the Leverhulme Trust (RPG-2017-231). C.K.M. acknowledges funding from the European Commission through a Marie Skłodowska Curie individual fellowship (101029807). M.C.G. acknowledges funding from the Alexander von Humboldt Stiftung (Humboldt-Professorship). We thank Aaron Naden for the FIB/STEM measurements (Engineering and Physical Sciences Research Council under grant numbers EP/L017008/1, EP/R023751/1 and EP/T019298/1).Direct deposition of organic light-emitting diodes (OLEDs) on silicon-based complementary metal–oxide–semiconductor (CMOS) chips has enabled self-emissive microdisplays with high resolution and fill-factor. Emerging applications of OLEDs in augmented and virtual reality (AR/VR) displays and in biomedical applications, e.g., as brain implants for cell-specific light delivery in optogenetics, require light intensities orders of magnitude above those found in traditional displays. Further requirements often include a microscopic device footprint, a specific shape and ultrastable passivation, e.g., to ensure biocompatibility and minimal invasiveness of OLED-based implants. In this work, up to 1024 ultrabright, microscopic OLEDs are deposited directly on needle-shaped CMOS chips. Transmission electron microscopy and energy-dispersive X-ray spectroscopy are performed on the foundry-provided aluminum contact pads of the CMOS chips to guide a systematic optimization of the contacts. Plasma treatment and implementation of silver interlayers lead to ohmic contact conditions and thus facilitate direct vacuum deposition of orange- and blue-emitting OLED stacks leading to micrometer-sized pixels on the chips. The electronics in each needle allow each pixel to switch individually. The OLED pixels generate a mean optical power density of 0.25 mW mm−2, corresponding to >40 000 cd m−2, well above the requirement for daylight AR applications and optogenetic single-unit activation in the brain.Publisher PDFPeer reviewe
Doctor of Philosophy
dissertationIn Part 1, we demonstrate the fabrication of organic light-emitting devices (OLEDs) with precisely patterned pixels by the spin-casting of Alq3 and rubrene thin films with dimensions as small as 10 μm. The solution-based patterning technique produces pixels via the segregation of organic molecules into microfabricated channels or wells. Segregation is controlled by a combination of weak adsorbing characteristics of aliphatic terminated self-assembled monolayers (SAMs) and by centrifugal force, which directs the organic solution into the channel or well. This novel patterning technique may resolve the limitations of pixel resolution in the method of thermal evaporation using shadow masks, and is applicable to the fabrication of large area displays. Furthermore, the patterning technique has the potential to produce pixel sizes down to the limitation of photolithography and micromachining techniques, thereby enabling the fabrication of high-resolution microdisplays. The patterned OLEDs, based upon a confined structure with low refractive index of SiO2, exhibited higher current density than an unpatterned OLED, which results in higher electroluminescence intensity and eventually more efficient device operation at low applied voltages. We discuss the patterning method and device fabrication, and characterize the morphological, optical, and electrical properties of the organic pixels. In part 2, we demonstrate a new growth technique for organic single crystals based on solvent vapor assisted recrystallization. We show that, by controlling the polarity of the solvent vapor and the exposure time in a closed system, we obtain rubrene in orthorhombic to monoclinic crystal structures. This novel technique for growing single crystals can induce phase shifting and alteration of crystal structure and lattice parameters. The organic molecules showed structural change from orthorhombic to monoclinic, which also provided additional optical transition of hypsochromic shift from that of the orthorhombic form. An intermediate form of the crystal exhibits an optical transition to the lowest vibrational energy level that is otherwise disallowed in the single-crystal orthorhombic form. The monoclinic form exhibits entirely new optical transitions and showed a possible structural rearrangement for increasing charge carrier mobility, making it promising for organic devices. These phenomena can be explained and proved by the chemical structure and molecular packing of the monoclinic form, transformed from orthorhombic crystalline structure
Pixel design and characterization of high-performance tandem OLED microdisplays
Organic Light-Emitting Diode (OLED) microdisplays - miniature Electronic Displays comprising a
sandwich of organic light emitting diode over a substrate containing CMOS circuits designed to function
as an active matrix backplane – were first reported in the 1990s and, since then, have advanced to the
mainstream. The smaller dimensions and higher performance of CMOS circuit elements compared to
that of equivalent thin film transistors implemented in technologies for large OLED display panels offer
a distinct advantage for ultra-miniature display screens. Conventional OLED has suffered from lifetime
degradation at high brightness and high current density. Recently, tandem-structure OLED devices have
been developed using charge generation layers to implement two or more OLED units in a single stack.
They can achieve higher brightness at a given current density. The combination of emissive-nature, fast
response, medium to high luminance, low power consumption and appropriate lifetime makes OLED a
favoured candidate for near-to-eye systems. However, it is also challenging to evaluate the pixel level
optical response of OLED microdisplays as the pixel pitch is extremely small and relative low light
output per pixel. Advanced CMOS Single Photon Avalanche Diode (SPAD) technology is progressing
rapidly and is being deployed in a wide range of applications. It is also suggested as a replacement for
photomultiplier tube (PMT) for photonic experiments that require high sensitivity. CMOS SPAD is a
potential tool for better and cheaper display optical characterizations.
In order to incorporate the novel tandem structure OLED within the computer aided design (CAD) flow
of microdisplays, we have developed an equivalent circuit model that accurately describes the tandem
OLED electrical characteristics. Specifically, new analogue pulse width modulation (PWM) pixel
circuit designs have been implemented and fabricated in small arrays for test and characterization
purposes. We report on the design and characterization of these novel pixel drive circuits for OLED
microdisplays. Our drive circuits are designed to allow a state-of-the-art sub-pixel pitch of around 5 μm
and implemented in 130 nm CMOS. A performance comparison with a previous published analogue
PWM pixel is reported. Moreover, we have employed CMOS SPAD sensors to perform detailed optical
measurements on the OLED microdisplay pixels at very high sampling rate (50 kHz, 10 μs exposure),
very low light level (2×10-4 cd/m2) and over a very wide dynamic range (83 dB) of luminance. This
offers a clear demonstration of the potential of the CMOS SPAD technology to reveal hitherto obscure
details of the optical characteristics of individual and groups of OLED pixels and thereby in display
metrology in general.
In summary, there are three key contributions to knowledge reported in this thesis. The first is a new
equivalent circuit model specifically for tandem structure OLED. The model is verified to provide
accurately illustrate the electrical response of the tandem OLED with different materials. The second is
the novel analogue PWM pixel achieve a 5μm sub-pixel pitch with 2.4 % pixel-to-pixel variation. The
third is the new application and successful characterization experiment of OLED microdisplay pixels
with SPAD sensors. It revealed the OLED pixel overshoot behaviour with a QIS SPAD sensor
Eurodisplay 2019
The collection includes abstracts of reports selected by the program by the conference committee
IMPROVE: collaborative design review in mobile mixed reality
In this paper we introduce an innovative application designed to make collaborative design review in the architectural and automotive domain more effective. For this purpose we present a system architecture which combines variety of visualization displays such as high resolution multi-tile displays, TabletPCs and head-mounted displays with innovative 2D and 3D Interaction Paradigms to better support collaborative mobile mixed reality design reviews. Our research and development is motivated by two use scenarios: automotive and architectural design review involving real users from Page\Park architects and FIAT Elasis. Our activities are supported by the EU IST project IMPROVE aimed at developing advanced display techniques, fostering activities in the areas of: optical see-through HMD development using unique OLED technology, marker-less optical tracking, mixed reality rendering, image calibration for large tiled displays, collaborative tablet-based and projection wall oriented interaction and stereoscopic video streaming for
mobile users. The paper gives an overview of the hardware and software developments within IMPROVE and concludes with results from first user tests
Optoelectronic properties of poly(fluorene) co‐polymer light‐emitting devices on a plastic substrate *
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/92131/1/1.2150379.pd
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