Contact Imaging: Simulation and Experiment

Ji, Honghao; Sander, David; Haas, Alfred; Abshire, Pamela

doi:10.1109/tcsi.2007.902409

Cited by 55 publications

(35 citation statements)

References 43 publications

(30 reference statements)

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“…As analyzed in [6,7,8,9,10,11], the spatial resolution can be improved by increasing D ls , or decreasing D obj and D PIX . D ls can be as long as several centimeters, which is mainly determined by the size of the POCT system.…”

Section: Introductionmentioning

confidence: 99%

Machine Learning Based Single-Frame Super-Resolution Processing for Lensless Blood Cell Counting

Huang

Jiang

Liu

et al. 2016

Sensors

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A lensless blood cell counting system integrating microfluidic channel and a complementary metal oxide semiconductor (CMOS) image sensor is a promising technique to miniaturize the conventional optical lens based imaging system for point-of-care testing (POCT). However, such a system has limited resolution, making it imperative to improve resolution from the system-level using super-resolution (SR) processing. Yet, how to improve resolution towards better cell detection and recognition with low cost of processing resources and without degrading system throughput is still a challenge. In this article, two machine learning based single-frame SR processing types are proposed and compared for lensless blood cell counting, namely the Extreme Learning Machine based SR (ELMSR) and Convolutional Neural Network based SR (CNNSR). Moreover, lensless blood cell counting prototypes using commercial CMOS image sensors and custom designed backside-illuminated CMOS image sensors are demonstrated with ELMSR and CNNSR. When one captured low-resolution lensless cell image is input, an improved high-resolution cell image will be output. The experimental results show that the cell resolution is improved by 4×, and CNNSR has 9.5% improvement over the ELMSR on resolution enhancing performance. The cell counting results also match well with a commercial flow cytometer. Such ELMSR and CNNSR therefore have the potential for efficient resolution improvement in lensless blood cell counting systems towards POCT applications.

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Section: Introductionmentioning

confidence: 99%

Machine Learning Based Single-Frame Super-Resolution Processing for Lensless Blood Cell Counting

Huang

Jiang

Liu

et al. 2016

Sensors

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“…The system model work in [4] assumes that the pixel DR performance is good enough to cover the image intensity range, and the pixel size is smaller than FWHM of the intensity profiles. However, the pixel DR needs to cover the maximum image intensity range.…”

Section: B Dynamic Range Modelmentioning

confidence: 99%

“…This leads to one fundamental limitation in the existing lensless microfluidic imaging systems: a large CIS pixel has better dynamic range (DR) or sensitivity, but results in a poor spatial resolution. Therefore, the trade-off between system spatial resolution and DR (or sensitivity) needs to be properly analyzed for optimizing the overall system design [4].…”

Section: Introductionmentioning

confidence: 99%

A Single-Frame Superresolution Algorithm for Lab-on-a-Chip Lensless Microfluidic Imaging

Huang

Liu

et al. 2015

IEEE Des. Test

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With the recent advance of microfluidics-based lab-on-a-chip technology, lensless microfluidic imaging system with super-resolution (SR) has become a promising solution to miniaturize the conventional bulky lens-based microscope for high-throughput cell detection under specified resolution. The previous lensless system employing multi-frame SR processing limits the throughput due to the need to capture sub-pixel movement of capillary flowing cells. In this paper, we introduce two single-frame SR algorithms: one is interpolation-based method and the other one is machine-learning-based method. Both methods have shown great potential for on-chip implementation for cell detection with balanced resolution and throughput.

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“…Thus, it is ideal for use in microdevices in which the object(s) of interest and the sensor are of a similar scale. [23][24][25] Efforts in this area have mainly been targeted at providing contact images of particles, cells, and other biological entities. Kovacs and co-workers were the first to demonstrate the use of shadow images from a camera chip attached to the bottom of a microfluidic culture chamber to monitor the activity of Caenorhabditis elegans nematodes (typical length, approximately 1 mm) that were maintained in a microfluidic environment.…”

mentioning

confidence: 99%

Quantitative Detection of Bioassays with a Low‐Cost Image‐Sensor Array for Integrated Microsystems

et al. 2009

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Contact Imaging: Simulation and Experiment

Cited by 55 publications

References 43 publications

Machine Learning Based Single-Frame Super-Resolution Processing for Lensless Blood Cell Counting

Machine Learning Based Single-Frame Super-Resolution Processing for Lensless Blood Cell Counting

A Single-Frame Superresolution Algorithm for Lab-on-a-Chip Lensless Microfluidic Imaging

Quantitative Detection of Bioassays with a Low‐Cost Image‐Sensor Array for Integrated Microsystems

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