Dr. Jiang graduated from the Shandong Med Univ, Jinan, Shandong, China (242 46 Prior 1 1 71) in 1992. She works in Houston, TX and 2 other locations and specializes in Family Medicine. Dr. Jiang is affiliated with Houston Methodist West Hospital and Memorial Hermann Southeast Hospital.
Oct 2010 to Dec 2010 Intern & Foreign Exchange Trader TraineeMORGAN STANLEY
Jul 2010 to Aug 2010 Intern
Education:
THE UNIVERSITY OF CHICAGO Chicago, IL Jan 2011 to Jan 2012 Master of Science in Financial MathematicsShanghai Jiao Tong University Jan 2009 to Jan 2011 Bachelor in FinanceSHANGHAI JIAO TONG UNIVERSITY Jan 2007 to Jan 2011 Bachelor of Engineering in Software Engineering
Jan 2007 to Present General managerHangzhou Jiaao Culture Communion Ltd. Co
Mar 2005 to Jan 2007 manager, recruit students and foreign staffManhan Restaurant
Dec 1999 to Jul 2001 Cashier & Manager Assistant
Education:
Liaoning University of Science and Engineering Shenyang, CN Sep 1995 to Jun 1999 Bachelor of Arts in Business AdministrationPalau Community College Jul 1996 to Jun 1998 certificate
Skills:
Speak fluent English and Mandarin, Strong management skills including: Planning, implementation and organisational skills, supervision and monitoring, coordination and coaching skills Excellent communication, interpersonal and collaborative skills Public Relations and small business skills Negotiation, promotion and liaising skills at all levels Loyal and trustworthy Excellent customer service and conflict resolution abilities Punctual, fast learner, able to acquire new skills to accomplis
Jul 2009 to 2000 Postdoctoral FellowIndiana University Bloomington, IN Sep 2004 to Jun 2009 Doctoral StudentIndiana University Bloomington, IN Jan 2005 to Dec 2007 Associate Instructor (full responsibility)Indiana State Department of Health Indianapolis, IN Jan 2007 to Apr 2007 InternshipUnited Nations Children's Fund (UNICEF), Beijing, P. R. China
Jun 2006 to Aug 2006 InternshipIndiana University Bloomington, IN Aug 2003 to Dec 2004 Teaching AssistantPeking Union Medical College Blood Disease Hospital, Tianjin, China
Jul 2002 to Jun 2003 Nurse
Education:
University of California San Francisco, Center for Tobacco Control Research and Education San Francisco, CA 2009 to 2013 Postdoctoral Research Fellow in Tobacco ControlIndiana University Bloomington, IN 2004 to 2009 PhD in Health BehaviorIndiana University Bloomington, IN 2003 to 2004 MS in Health PromotionTsinghua University, Peking Union Medical College, School of Nursing, Beijing, P.R.China 1998 to 2002 BSN in Nursing
Skills:
Area of Specialization: co-use of tobacco and alcohol, policy analysis, tobacco marketing
License Records
Nan Jiang
License #:
E062251 - Expired
Category:
Emergency medical services
Issued Date:
Jan 1, 2007
Expiration Date:
Dec 31, 2008
Type:
Ventura County EMS Agency
Nan Jiang
License #:
P27250 - Active
Category:
Emergency medical services
Issued Date:
Jan 5, 2009
Expiration Date:
May 31, 2017
Name / Title
Company / Classification
Phones & Addresses
Nan Jiang President
Hedere Technologies Ltd
6050 W Eastwood Ave, Chicago, IL 60630
Nan Jiang
Far East Imports LLC Nondurable Goods, Nec, Nsk · Whol Nondurable Goods
577 Crystalberry Ter, San Jose, CA 95129 10217 Park Cir W, Cupertino, CA 95014
Nan Jiang - Stanford CA, US William J. Dally - Stanford CA, US
International Classification:
H04L 12/24
US Classification:
370216, 370244
Abstract:
Aspects relate to methods, devices and manufacturing relating to routing networks including a method for routing data units. The data units are individually routable through a routing network. A reservation request data unit is received over the routing network and from a sender. At least one speculative data unit associated with the reservation request data unit from the sender is received. The at least one speculative data unit is dropped in response to the at least one speculative data unit being blocked within the routing network. The sender is provided, over the routing network, a negative acknowledgement data unit that indicates the dropping of the at least one speculative data unit. The sender is provided a grant data unit indicating a start time. After the start time, at least one non-speculative data unit corresponding to the reservation request from the sender is received.
Absolute Position Detection Within 1 Revolution Using 3-Channel Incremental Encoders With High Resolution Index Track
Prasad V. Venugopal - Sunnyvale CA Nan Jiang - Fremont CA
Assignee:
Hewlett-Packard Company - Palo Alto CA
International Classification:
G01D 534
US Classification:
25023113
Abstract:
The quasi-absolute encoder module determines absolute position within one mechanical rotation. The encoder module includes a three channel position encoder and detection circuitry that includes a read-only memory (ROM). There are three channels: A, B, and I. Channels A and B have four periods and channel B is offset from channel A by 90. degree. in phase. Channel I has a unique sequence. The address generated by sampling this unique sequence corresponds to an address in ROM. The address indicates the position of the rotating shaft on which the codewheel is attached.
Absolute Position Detection Within 1 Revolution Using 3-Channel Incremental Encoders With High Resolution Track
Prasad V. Venugopal - Sunnyvale CA Nan Jiang - Fremont CA
Assignee:
Hewlett-Packard Company - Palo Alto CA
International Classification:
G01D 534
US Classification:
25023113
Abstract:
The quasi-absolute encoder module determines absolute position within one mechanical rotation. The encoder module includes a three channel position encoder and detection circuitry that includes a read-only memory (ROM). There are three channels: A, B, and I. Channels A and B have four periods and channel B is offset from channel A by 90. degree. in phase. Channel I has a unique sequence. The address generated by sampling this unique sequence corresponds to an address in ROM. The address indicates the position of the rotating shaft on which the code wheel is attached.
Scalable In-Network Computation For Massively-Parallel Shared-Memory Processors
- Santa Clara CA, US Nan Jiang - Santa Clara CA, US Larry Robert Dennison - Menden MA, US Gregory M. Thorson - Palo Alto CA, US
International Classification:
H04L 12/18 H04L 12/741
Abstract:
A network device configured to perform scalable, in-network computations is described. The network device is configured to process pull requests and/or push requests from a plurality of endpoints connected to the network. A collective communication primitive from a particular endpoint can be received at a network device. The collective communication primitive is associated with a multicast region of a shared global address space and is mapped to a plurality of participating endpoints. The network device is configured to perform an in-network computation based on information received from the participating endpoints before forwarding a response to the collective communication primitive back to one or more of the participating endpoints. The endpoints can inject pull requests (e.g., load commands) and/or push requests (e.g., store commands) into the network. A multicast capability enables tasks, such as a reduction operation, to be offloaded to hardware in the network device.
Injection Limiting And Wave Synchronization For Scalable In-Network Computation
A network device configured to perform scalable, in-network computations is described. The network device is configured to process pull requests and/or push requests from a plurality of endpoints connected to the network. A collective communication primitive from a particular endpoint can be received at a network device. The collective communication primitive is associated with a multicast region of a shared global address space and is mapped to a plurality of participating endpoints. The network device is configured to perform an in-network computation based on information received from the participating endpoints before forwarding a response to the collective communication primitive back to one or more of the participating endpoints. An injection policy comprising the issuing of credits enables each endpoint to limit the amount of collective communication primitives injected into the network simultaneously to reduce network congestion caused by increased network traffic due to the multicast capability of the network devices.
Scalable In-Network Computation For Massively-Parallel Shared-Memory Processors
- Santa Clara CA, US Nan Jiang - Santa Clara CA, US Larry Robert Dennison - Menden MA, US Gregory M. Thorson - Palo Alto CA, US
International Classification:
H04L 29/08 H04L 12/18 H04L 12/741
Abstract:
A network device configured to perform scalable, in-network computations is described. The network device is configured to process pull requests and/or push requests from a plurality of endpoints connected to the network. A collective communication primitive from a particular endpoint can be received at a network device. The collective communication primitive is associated with a multicast region of a shared global address space and is mapped to a plurality of participating endpoints. The network device is configured to perform an in-network computation based on information received from the participating endpoints before forwarding a response to the collective communication primitive back to one or more of the participating endpoints. The endpoints can inject pull requests (e.g., load commands) and/or push requests (e.g., store commands) into the network. A multicast capability enables tasks, such as a reduction operation, to be offloaded to hardware in the network device.
Techniques For Reducing Congestion In A Computer Network
- Santa Clara CA, US Nan Jiang - Santa Clara CA, US John Wortman - Santa Clara CA, US Alex Ishii - Santa Clara CA, US Mark Hummel - Santa Clara CA, US Rich Reeves - Santa Clara CA, US
International Classification:
H04L 12/801 H04L 12/825 H04L 12/26
Abstract:
Multiple processors are often used in computing systems to solve very large, complex problems, such as those encountered in artificial intelligence. Such processors typically exchange data among each other via an interconnect fabric (such as, e.g., a group of network connections and switches) in solving such complex problems. The amount of data injected into the interconnect fabric by the processors can at times overwhelm the interconnect fabric preventing some of the processors from communicating with each other. To address this problem, techniques are disclosed to enable, for example, processors that are connected to an interconnect fabric to coordinate and control the amount of data injected so that the interconnect fabric does not get overwhelmed.
- Glen Ellyn IL, US Nan Jiang - Lincolnshire IL, US Alejandro Tatay de Pascual - Valencia, ES
International Classification:
G06K 9/32 G06K 9/52 G06K 9/62 G06F 17/30
Abstract:
An image identification system may identify key points on a known image, variations of the known image in different levels of blur, and an unidentified image. One or more geometric shapes may be formed from the key points. A match between the unidentified image and either the known image or a blurred variation of the known image may be determined by comparison of the respective geometric shapes.
News
This Smart Tattoo Changes Color When Your Blood Sugar Is High
There's hope it could be realized. Nan Jiang, one of the study's authors, said the smart tattooscould be applied to athletes to monitor their health levels, and even astronauts to monitor their condition while in space.
Date: Oct 02, 2017
Category: Health
Source: Google
Youtube
JJ Lin - Jiangnan () Lyrics [Color Coded |Chn...
All rights to the original owners Artist: JJ Lin (... Song: Jiangnan ...