Tunable and Storage Potential Wells using Microring Resonator System for Biocell Trapping and Delivery

•

0 likes•278 views

In this work, we propose the technique that can be used to trap/delivery bio-cell by using the concept of dark solitons and potential well, in which the trapping force is formed by using the intense optical vortices generated within the series ring and the PANDA ring resonator, the microscopic bio-cell can be trapped and moved dynamically, in which the valley of the dark soliton is generated and controlled within the PANDA ring resonator by the control port signals.

8/1/2014 IEEE Xplore Abstract - Tunable and storage potential wells using microring resonator system for bio-cell trapping and deliv...
http://ieeexplore.ieee.org/xpl/login.jsp?tp=&arnumber=5700940&url=http%3A%2F%2Fieeexplore.ieee.org%2Fxpls%2Fabs_all.jsp%3Farnumber%3D5700940 2/2
About IEEE Xplore | Contact | Help | Terms of Use | Nondiscrimination Policy | Site Map | Privacy & Opting Out of Cookies
A not-for-profit organization, IEEE is the w orld's largest professional association for the advancement of technology.
© Copyright 2014 IEEE - All rights reserved. Use of this w eb site signifies your agreement to the terms and conditions.

A system of microring resonators (MRRs) is presented to generation entangled photon. Different time slot for continuous variable quantum key distribution (CVQKD) use is applicable in optical wireless link. Chaotic behavior of a soliton pulse within the device can be presented respect to the Kerr nonlinear type of light in the MRR devices. Continuous spatial and temporal signals are generated spreading over the spectrum. The CVQKD is formed using the localized spatial soliton pulse. Here localized temporal soliton with FWHM and FSR of 0.2 ps and 0.58 ns is obtained respectively. The spatial soliton pulse has a FWHM of 80 pm. Transmission of soliton pulse with FWHM of 1.5 ps is simulated along the long distance fiber optics where the polarized photons are formed incorporating with the polarization control unit into the MRRs, which allows different time slot entangled photons to be randomly formed.

Generation of Quantum Photon Information Using Extremely Narrow Optical Tweez...

University of Malaya (UM)

A system of microring resonator (MRR) is presented to generate extremely narrow optical tweezers. An add/drop filter system consisting of one centered ring and one smaller ring on the left side can be used to generate extremely narrow pulse of optical tweezers. Optical tweezers generated by the dark-Gaussian behavior propagate via the MRRs system, where the input Gaussian pulse controls the output signal at the drop port of the system. Here the output optical tweezers can be connected to a quantum signal processing system (receiver), where it can be used to generate high capacity quantum codes within series of MRR’s and an add/drop filter. Detection of the encoded signals known as quantum bits can be done by the receiver unit system. Generated entangled photon pair propagates via an optical communication link. Here, the result of optical tweezers with full width at half maximum (FWHM) of 0.3 nm, 0.8 nm and 1.6 nm, 1.3 nm are obtained at the through and drop ports of the system respectively. These results used to be transmitted through a quantum signal processor via an optical computer network communication link.

Deep two-photon brain imaging with a red-shifted fluorometric Ca2+ indicator

PetteriTeikariPhD

Journal club for the article by Carsten Tischbirek et al. (2015): Tischbirek, Carsten, et al. "Deep two-photon brain imaging with a red-shifted fluorometric Ca2+ indicator." Proceedings of the National Academy of Sciences 112.36 (2015): 11377-11382. http://dx.doi.org/10.1073/pnas.1514209112 Alternative download link: https://dl.dropboxusercontent.com/u/6757026/slideShare/journalClub_Dec2015_v2.pdf

Windows Server+Photon Server環境でもFluentd+Elasticsearch+Kibanaを活用して各種情報を可視化する...

GMO GlobalSign Holdings K.K.

Text Analysis of Academic Papers Archived in Institutional Repositories

Okamoto Laboratory, The University of Electro-Communications

6043.ppt

john tamil selvan

Horton budget

bmh2901

Advanced Technology Information Processing Systems this presentation was provided in the Canada Taiwan meeting in April 2005. Graham.A. Jullien, iCORE Research Chair, Wael Badawy, iCORE Research Associate and Director of the Digital Video Laboratory, Dr. V.S. Dimitrov, iCORE Research Associate and member of the Centre for Information Securityand Cryptography Dr. O. Yadid-Pecht, iCORE Research Associate, Imaging and Sensor Technology Laboratory

How Can AI and IoT Power the Chemical Industry?

Xiaonan Wang

DCC Keynote 2007

Carole Goble

Advanced java

Felixits

Felix-ITs is one of the best training institutes in Pune for Mobile Application Development. Felix-ITs conducts the mobile application trainings/ courses in Pune on Android, iOS, HTML5 & CSS3. The thing that distinguishes Felix-ITs from other mobile application training institutes is that our main focus lies in providing in-depth knowledge of key concepts to our participants. We aim to mould students to become expert professionals by following a step-by step training process. Each of our courses is designed in a way that begins with the basics of mobile application technology, moving to the most advanced concepts, with every step.

Java

Felixits

Java is the most commonly used as well as the most popular programming language today. Be it creating a web application or a mobile application, Java is the most preferred tool by most developers. It is a program that helps create interactive content for web pages like ecommerce websites. Felix-ITs is a training institute in Pune that provides Java courses for freshers as well as experienced professionals in the field. As this programming language is quite popular, the demand for developers with expertise in Java has increased. Moreover, this demand for Java programmers is here to stay. Felix-Its' Java courses are not only appropriate for people who want to have a career in mobile and web application development, but it is also great for professionals who want to upgrade their knowledge. Here are the Java courses offered by Felix-Its.

Java and Adv Java

Felixits

HTML5 Css3 Enter the profitable world of web design and development with the new age combo of HTML5 and CSS3. You learn introductory concepts and prerequisites of grasping the concept right. You work with features like 2D animations, menus, fonts, and 2D. With advanced coverage, you will be ready to build solutions like enterprise sites or ecommerce portals easily. LEARN MORE Java Be introduced to OOPS concepts and how Java implements OOPS into its technology development requirement. Be it the first ‘Hello World’ program or developing complex applications with the Java collections framework, you can get a thorough fluency in Java programming for developing modern day tech solutions for clients in the real- world business scenario

Java

Felixits

earn Java with the best institute for java training in pune. Get advanced java training in pune with complete java practicals and on the job training in pune. Java training in pune with job support and java training practicals. Complete java training package from the best java classes in pune. At Felix ITs you have the opportunity to master Java core concepts from the industry veterans. Our hands-on training sessions are just what you need to make the leap from a student to a real-world professional with Java expertise.

Java

Felixits

Learn Java with the best institute for java training in pune. Get advanced java training in pune with complete java practicals and on the job training in pune. Java training in pune with job support and java training practicals. Complete java training package from the best java classes in pune. At Felix ITs you have the opportunity to master Java core concepts from the industry veterans. Our hands-on training sessions are just what you need to make the leap from a student to a real-world professional with Java expertise.

ACCESSIBILITY OF MOBILE CYBER PHYSICAL SYSTEM 02

Partha Sarathi Kar

Bionic eyeJeffrey Funk

BHL Technologies: Review for BHL-Australia

Chris Freeland

PresentacStandardization of Online Laboratories for Education: IEEE-SA STD 1...

Miguel Rodriguez Artacho

Standardization of Online Laboratories for Education: IEEE-SA STD 1876/2019

Miguel R. Artacho

ASK-to-PSK Generation based on Nonlinear Microring Resonators Coupled to One ...

University of Malaya (UM)

All-optical logic XOR/XNOR gate operation using microring and nanoring reson...

University of Malaya (UM)

In this paper, a novel system of simultaneous optical logic AND and OR gates using dark -bright soliton conversion within the add/drop optical filter system is proposed. The input logic „0‟ and control logic „0‟ are formed by using the dark soliton pulse (D) trains. By using the dark-bright soliton conversion behavior within the π/2 phase shift device, we found that the simultaneous optical logic AND and OR gates at the drop and through ports can be randomly formed, respectively.

Similar to Tunable and Storage Potential Wells using Microring Resonator System for Biocell Trapping and Delivery

Customer Success Story: IEEE Xplore Saves Time

IEEE Xplore Digital Library

44rd CEN WS/LT meeting PT social data

Joris Klerkx

Structural Biology in the Clouds: A Success Story of 10 years

AlexandreBonvin2

Csedu2018 keynote saliah-hassane_final

Hamadou Saliah-Hassane

Sinnott Paper

Johanna Green

OBJEVTE MOŽNOSTI PUBLIKOVÁNÍ S VYDAVATELSTVÍM IEEE - by ESZTER LUKACS

Ustredni knihovna VUT

Ieee orientation 2013 bracusbSadaf Noor

ATIPS - Advanced Technology Information Processing Systems

Wael Badawy

How Can AI and IoT Power the Chemical Industry?

DCC Keynote 2007

Advanced java

Java

Java and Adv Java

Java

Java

ACCESSIBILITY OF MOBILE CYBER PHYSICAL SYSTEM 02

Partha Sarathi Kar

Bionic eyeJeffrey Funk

BHL Technologies: Review for BHL-Australia

Chris Freeland

PresentacStandardization of Online Laboratories for Education: IEEE-SA STD 1...

Miguel Rodriguez Artacho

Standardization of Online Laboratories for Education: IEEE-SA STD 1876/2019

Miguel R. Artacho

Similar to Tunable and Storage Potential Wells using Microring Resonator System for Biocell Trapping and Delivery (20)

Customer Success Story: IEEE Xplore Saves Time

44rd CEN WS/LT meeting PT social data

Structural Biology in the Clouds: A Success Story of 10 years

Csedu2018 keynote saliah-hassane_final

Sinnott Paper

OBJEVTE MOŽNOSTI PUBLIKOVÁNÍ S VYDAVATELSTVÍM IEEE - by ESZTER LUKACS

Ieee orientation 2013 bracusb

ATIPS - Advanced Technology Information Processing Systems

How Can AI and IoT Power the Chemical Industry?

DCC Keynote 2007

Advanced java

Java

Java and Adv Java

Java

ACCESSIBILITY OF MOBILE CYBER PHYSICAL SYSTEM 02

Bionic eye

BHL Technologies: Review for BHL-Australia

PresentacStandardization of Online Laboratories for Education: IEEE-SA STD 1...

Standardization of Online Laboratories for Education: IEEE-SA STD 1876/2019

More from University of Malaya (UM)

ASK-to-PSK Generation based on Nonlinear Microring Resonators Coupled to One ...

University of Malaya (UM)

All-optical logic XOR/XNOR gate operation using microring and nanoring reson...

University of Malaya (UM)

Simulation and Analysis of Multisoliton Generation Using a PANDA Ring Resonat...

University of Malaya (UM)

A novel system of multisoliton generation using nonlinear equations of the propagating signals is presented. This system uses a PANDA ring resonator incorporated with an add/drop filter system. Using resonant conditions, the intense optical fields known as multisolitons can be generated and propagated within a Kerr-type nonlinear medium. The present simulation results show that multisolitons can be controlled by using additional Gaussian pulses input into the add port of the PANDA system. For the soliton pulse in the microring device, a balance should be achieved between dispersion and nonlinear lengths. Chaotic output signals from the PANDA ring resonator are input into the add/drop filter system. Chaotic signals can be filtered by using the add/drop filter system, in which multi dark and bright solitons can be generated. In this work multi dark and bright solitons with an FWHM and an FSR of 425pm and 1.145 nm are generated, respectively, where the Gaussian pulse with a central wavelength of 1.55 μm and power of 600 mW is input into the system.

Characterisation of bifurcation and chaos in silicon microring resonatorUniversity of Malaya (UM)

Decimal Convertor Application for Optical Wireless Communication by Generatin...

University of Malaya (UM)

Two systems consist of microring resonators (MRRs) and an add/drop filter are used to generate signals as localized multi wavelengths. Quantum dense encoding can be performed by output signals of selected wavelengths incorporated to a polarization control system. Therefore dark and bright optical soliton pulses with different time slot are generated. They can be converted into digital logic quantum codes using a decimal convertor system propagating along a wireless networks. Results show that multi soliton wavelength, ranged from 1.55 m to 1.56 m with FWHM and FSR of 10 pm and 600 pm can be generated respectively. Keywords- Micro Ring Resonator, Quantum Dense Coding (QDC), Wireless network communication system.

Cryptography Scheme of an Optical Switching System Using Pico/Femto Second So...

University of Malaya (UM)

We propose a system of microring resonators (MRRs) incorporating with an add/drop filter system. Optical soliton can be simulated and used to generate entangled photon, applicable in single and multiple optical switching. Chaotic signals can be generated via the MRRs system. Therefore continuous spatial and temporal signals are generated spreading over the spectrum. Polarized photons are formed incorporating the polarization control unit into the MRRs, which allows different time slot entangled photons to be randomly formed. Results show the single soliton pulse of 0.7 ps where the multi soliton pulse with FSR and FWHM of 0.6 ns and 20 ps are generated using the add/drop filter system. Here Ultra-short single soliton pulse with FWHM=42 fs can be simulated. These pulses are providing required communication signals to generate pair of polarization entangled photons among different time frame where the polarization control unit and polarizer beam splitter (PBS) are connected to the ring resonator system.

Frequency-Wavelength Trapping by Integrated Ring Resonators For Secured Netwo...

University of Malaya (UM)

Optical pulse trapping via a series of microring resonator (MRR) is presented. Large bandwidth of optical soliton is generated by input pulse propagating within the MRRs. Distinguished discrete wavelength or frequency pulses can be generated by using localized spatial pulses via a networks communication system. Quantum codes can be generated by using a polarization control unit and a beam splitter, incorporating to the MRRs. Here frequency band of 10.7 MHz and 16 MHz and wavelengths of 206.9 nm, 1448 nm, 2169 nm and 2489 nm are localized and obtained and used for quantum codes generation applicable for secured networks communication.

Dark-Bright Solitons Conversion System for Secured and Long Distance Optical ...

University of Malaya (UM)

We suggest a new purpose of a security scheme by employing the nonlinear behaviors of temporal dark and bright solitons amongst a micro-ring resonator system for signal security application. The chaotic signal is generated, where the required bright soliton pulse can be recovered and discovered by an add/drop filtering device. By using the reserve ring parameters, simulation results obtained have demonstrated that the soliton conversion can be performed. In application, the chaotic signal is generated and formed by the dark soliton inside a nonlinear micro-ring device. The different temporal soliton response time can be seen, the response times of 169 and 84 ns are mentioned for temporal dark and bright solitons, respectively, which can also be used to figure the security key. The technique of optical conversion can be use to improve the optical communication network systems.

Secured Transportation of Quantum Codes Using Integrated PANDA-Add/drop and T...

University of Malaya (UM)

New system of quantum cryptography for communication networks is proposed. Multi optical Soliton can be generated and propagated via an add/drop interferometer system incorporated with a time division multiple access (TDMA) system. Here the transportation of quantum codes is performed. Chaotic output signals from the PANDA ring resonator are inserted into the add/drop filter system. Using the add/drop filter system multi dark and bright solitons can be obtained and used to generate entangled quantum codes for internet security. In this research soliton pulses with FWHM and FSR of 325 pm and 880 nm are generated, respectively.

Determination Of Fwhm For Solition Trapping

University of Malaya (UM)

In this study an interesting system in which a bright and dark soliton pulse can be stopped inside a nonlinear waveguide is presented. Here, we propose a system consisting of a series of ring resonators for optical trapping within a nonlinear waveguide. The bright and dark solitons can be controlled and slowed down within the waveguide. The FWHM for the output signals are calculated and used as an optical memory. Bright and dark soliton behaviors within a micro and nano ring resonator are also investigated and described. The required pulse is filtered and amplified, can be controlled and localized within the system. The localized bright and dark solitons are stopped by controlling the input power,which means that the photon stopping can be controlled by light in a ring resonator.

A Study oF Dynamic Optical Tweezers Generation For Communication Networks

University of Malaya (UM)

We propose a novel system of the dynamic optical tweezers generated by a dark soliton in the fiber optic loop. A dark soliton known as an optical tweezer is amplified and tuned within the microring resonator (MRR) system. The required tunable tweezers with different widthsand powers can be controlled. The analysis of dark-bright soliton conversion using a dark soliton pulse propagating within a MRR is analyzed. The control dark soliton is input into the system via the add port of the add/drop filter. The dynamic behavior of the dark-brightsoliton conversion is observed. The required stable signal is obtained via a drop and throughput ports of the add/drop filter with some suitable parameters. In application, generation of optical tweezers and transportation can be realized by using the proposed system, where the communication network is performed.

University of Malaya (UM)

A molecular cryptography technique using optical tweezers, is proposed. The optical tweezer transports the molecules in the communication system. The optical tweezer generated by the dark soliton is in the form of a potential well. The dark soliton propagates inside nonlinear microring resonator (NMRR). Transportation of molecules is implemented when the dark soliton is used as input pulse. The input bright soliton control the output signal at the drop port of the system. Output optical tweezers can be connected to the quantum signal processing system consisting of transmitter and the receiver. The transmitter is used to generate the high capacity quantum codes within the series of MRR’s and anadd/drop filter. The receiver will detect the encoded signals known as quantum bits. The transmitter will generate the entangled photon pair which propagates via an optical communication link. Here the smallest optical tweezer with respect to the full width at half maximum FWHM is 17.6 nm in the formof potential well is obtained and transmitted through quantum signal processor via an optical link.

Controlling Nonlinear Behavior of a SMRR for Network System Engineering

University of Malaya (UM)

This research is used to control the nonlinear behavior of silicon microring resonators, MRR’s such as chaos and bifurcation. Increasing of nonlinear refractive indices, coupling coefficients and radius of the SMRR leads to descend input power and round trips wherein the bifurcation occurs. As result, bifurcation or chaos behaviors are seen at lower input power of 44 W, where the nonlinear refractive index is n2=3.2×10−20 m2/W. Smallest round trips can be seen for the R=40 µm and  0.1 respectively. Signals from the SMRR are passing through a polarizer beam splitter to generate quantum binary codes which are used in wireless network communication.

Optical Wired/Wireless Communication Using Soliton Optical Tweezers

University of Malaya (UM)

The aim of this study is to generate nano optical tweezers to be connected to an optical quantum signal processing system in order to transmit quantum photon via an optical communication link. A system of microring resonator (MRR) known as Half-Panda is proposed to generate nano optical tweezers. Optical tweezers can be used to transport molecules in a communication link. The dark soliton propagates inside nonlinear MRR. Transportation of molecules or photons is implemented when the dark soliton is used as input pulse. The input Gaussian soliton is used to control the output signal at the through and drop ports of the system. Output nano optical tweezers can be connected to the quantum signal processing system consisting of a receiver and transmitter. The receiver will detect the signals of optical tweezers and transmit them via wired/wireless as quantum bits. The transmitter will generate the entangled photon pair which propagates via an optical communication link. Here the smallest nano optical tweezers signals with width at half maximum (FWHM) of 4.2 nm is obtained where the free spectrum range (FSR) of 50 nm is simulated.

Ultra-short Multi Soliton Generation for Application in Long Distance Commun...

University of Malaya (UM)

Generation of picometer optical soliton pulses is investigated using a nonlinear PANDA ring resonator system connecting to an add/drop filter system. The objectives of the research are to employ systems of microring resonator (MRR) to generate binary signals to be carried out along fiber optic communication. Effective parameters such as refractive indices of a silicon waveguide, coupling coefficients (), coupling loss, radius of the ring (R) and the input power can be selected properly to operate the nonlinear behavior. The input Gaussian laser pulses with power of 600 mW are inserted into the system. The central wavelength of the input power has been selected to λ0=1.55 µm where the nonlinear refractive index of the medium is n2=2.6×10−17 m2 W−1. Therefore binary signals generated by the add/drop filter system can be converted to secure codes where the decoding process of the transmitted codes can be obtained at the final step. Here, multi soliton pulses with full width at half maximum (FWHM) of 325 could be generated, converted to secure codes and finally detected over 70 km optical fiber communication link.

Single Soliton Bandwidth Generation and Manipulation by Microring Resonator

University of Malaya (UM)

In this paper, we propose a system for chaotic signal generation using a microring resonator (MRR) fiber optic system. This system uses a regular laserdiode as input power and can be incorporated with an optical add/drop filter system. When light from the laser diode feedbacks to the fiber ring resonator, the actual chaotic signal is produced by using the appropriate fiber ring resonator parameters and also the laser diode input power. The filtering process of the chaotic signals occurs during the round-trip of the pulse within the ring resonators. The single soliton pulses generation and bandwidth manipulation of the pulse can be performed using the add/drop system. Results obtained have established particular possibilities from the application. The obtained results show the effects of coupling coefficients on the bandwidth of the single soliton pulse, where the chaotic behaviors of the input pulses are presented.

NEW SYSTEM OF CHAOTIC SIGNAL GENERATION BASED ON COUPLING COEFFICIENTS APPLI...

University of Malaya (UM)

The nonlinear behavior (chaotic) of light traveling in an optical fiber ring resonator such as an add/drop system is presented. The chaotic behavior is considered to be a beneficial effect that can be used in the communication system. Such a system can be used to secure the information signals, therefore, the ability of chaotic carriers to synchronize in a communication system is performed. The used optical material is InGaAsP/InP regarding to suitable parameters of the system. The nonlinear refractive index is fixed to n2 = 3.8 × 10−20 m2 /W, and the 20,000 iterations of round-trip within the system is simulated. The input powers are selected at 1 W, where the coupling coefficient of the system varies according to two critical cases, where 0    0.1 and 0.1  1. As a results, larger coupler coefficient corresponds to lower input power for the case of 0    0.1 and smaller coupling coefficient of the system is corresponds to lower input power when 0.1  1. To optimize the microring systems, Lower input power is recommended in many applications in optical optical communication systems.

Chaotic Signal Generation and Trapping Using an Optical Transmission Link

University of Malaya (UM)

Chaotic soliton can be generated using a nonlinear PANDA system. The research uses microring resonator (MRR) to generate and trap chaotic signals along fiber optic communication. The parameters such as refractive indices of a silicon waveguide, coupling coefficients ( ), coupling loss, radius of the ring (R) and the input power can be selected properly to operate the nonlinear behavior. The input Gaussian laser pulses with power of 0.45 W are inserted into the system. The central wavelength of the input power has been selected to λ0=1.55 µm where the nonlinear refractive index of the medium is n2=1.3×10−17 m2 W−1 . The generated chaotic signals with Full at Half Maximum of 24 pm can be transmitted along the fiber optic with length of 195 km. The trapping of chaotic signals can be obtained at the end of the transmission link. Here signals with 600 fm bandwidth could be trapped within the system.

LOGIC CODES GENERATION AND TRANSMISSION USING AN ENCODING-DECODING SYSTEM

University of Malaya (UM)

Nonlinear behaviors of light such as chaos can be observed during propagation of a Gaussian laser beam inside a single ring resonator system. Chaotic signals can be employed to generate data of logic codes to be transmitted along the fiber optic communication. Controlling of the chaotic signals can be implemented by the parameter of the system such as coupling coefficient, the ring’s radius, coupling loss and input power. The central wavelength of the input Gaussian laser pulse has been selected to λ0=1550 nm where the nonlinear refractive index of the medium is n2=1.4×10−13 m2 W−1. Therefore the data of logic codes generated by the single ring resonator system can be converted to transmitting secured codes where the decoding process of the transmitted codes can be obtained at the end of the transmission link. Here generation of logic code of “101010101011010101011101011110101101010101010110101” is performed, encoded and decoded over 50 km fiber optics. Thus secured transmitting of signals can be obtained along the long distance fiber communication.

Generation of Nanometer Optical Tweezers Used for Optical Communication Netw...

University of Malaya (UM)

A system of Half-Panda microring resonator (MRR) is proposed to generate ultra-short nanometer (nm) optical tweezers. The dark soliton propagates inside nonlinear MRR. Molecules or photons transport within the system when the dark soliton is used as input pulse. Nano optical tweezers can be generated and used to many applications in optical communication networks. Here the smallest nano optical tweezers signals with full width at half maximum (FWHM) of 9 nm is obtained where the free spectrum range (FSR) of 50 nm is simulated.

More from University of Malaya (UM) (20)

ASK-to-PSK Generation based on Nonlinear Microring Resonators Coupled to One ...

All-optical logic XOR/XNOR gate operation using microring and nanoring reson...

Simulation and Analysis of Multisoliton Generation Using a PANDA Ring Resonat...

Characterisation of bifurcation and chaos in silicon microring resonator