Event on 2012-08-28 09:00:00
Description
This course will provide the students with the necessary skills to plan, install, configure and administer a ForgeRock OpenAM deployment.
The main goal of the course is to give a quick understanding and hands-on experience, so students can control the most important functions of ForgeRock OpenAM and manage a production deployment.
Course material is in English and class will be delivered in Português.Audience:
The course is aimed at system administrators, integrators, consultants, architects and developers installing and configuring ForgeRock OpenAM.Prerequisites:
- A basic knowledge of Unix commands
- A basic understanding of how LDAP works
- An appreciation of HTTP and web applications
- A basic knowledge of Java would be beneficial, although programming experience is not required
- Identity Management Concepts: Provisioning, Authentication, Authorization
- Access Management: Access Control, Single Sign On, Web Access Management, Federation
- ForgeRock OpenAM Architecture: Authentication, Authorization, Federation
- Policy Agents
- Deployment components
- Supported platforms
- Hardware requirements
- Installation process
- Deployment scenarios: Single instance, Distributed Authentication, High availability
- Lab: Installation
- Integration scenarios
- Policy Agents
- ForgeRock OpenAM web services interface: SOAP/WSDL, REST
- Client SDK
- Lab: Apache Policy agent installation; REST example
- Data stores for ForgeRock OpenAM
- Understanding realms
- Identity repositories
- Lab: Creating and using a realm
- ForgeRock OpenAM Authentication process
- Authentication Architecture: Server side, Client side
- Sessions: Authentication states, Session service
- Configuring authentication
- Authentication chains
- Post authentication plug-in
- Programmatic authentication
- Lab: Configuring authentication modules
- Authentication Web User interface
- Customizing the Web User Interface: Files, directory structure, JSP templates
- Process of creating an authentication module
- Adding a customized authentication module
- Lab: Create, install and use a new authentication module; Install a post authentication plug-in
- Authorization policies overview
- Policy Component Functionality: Definition, storage, administration
- Configuring Policies
- Lab: Create polices and use more configuration options of the Apache Policy Agent
- Concepts: SAML 1.1 & 2.0; Liberty ID-FF; Fedlet; ID-WSF
- Configuring SAML 2.0 in ForgeRock OpenAM as an IdP; as an SP
- The Fedlet
- SAML 2.0 extending functionality with plug-ins - Account mapper- Attribute mapper- Context mapper
- Lab: Configure ForgeRock OpenAM in a Federated environment using SAML2 - Configure as an IdP- Configure as an SP- Deploy and use a Fedlet
at Global Code São Paulo (Sede Central)
327 Av. Bernardino de Campos
São Paulo, Brazil
CERN: BIG QUESTIONS, BIG SCIENCE, BIG TECHNOLOGY
Event on 2012-08-23 09:00:00
CERN: BIG QUESTIONS, BIG SCIENCE, BIG TECHNOLOGYTHURSDAY 23RD AUGUSTTime: 9:00-12:00venue: APPLETON TOWER, THEATRE 4
ticket: £15
-------------------------------------------------------------------------------------------------------------------------------------
This event is aimed at both the computing & science communities as well as those with a natural curiosity in matters of the universe. Bringing together experts from different areas of CERN and the LHC, each speaker will talk about the far reaching impact their work has, both on the world at large and the physics and computing communities within it.
CERN, the European Organization for Nuclear Research, is one of the world’s largest and most respected centres for scientific research. Its business is fundamental physics, finding out what the Universe is made of and how it works. At CERN, the world’s largest and most complex scientific instruments are used to study the basic constituents of matter, the fundamental particles. By studying what happens when these particles collide, physicists learn about the laws of Nature.
The Large Hadron Collider (LHC) is the latest tool to investigate the fundamental building blocks of our universe. It is buried 100m underground, accelerates protons close to the speed of light, around a 27Km ring and then collides them to recreate the early universe. It serves as a discovery machine that could stimulate a complete rethink of modern physics.
Close to 10,000 physicists work on the experiments that use the LHC and while planning for it began in the mid-1980s, it can trace its ancestry back to the methods used to discover the electron in 1897.
------------------------------------------------------------------------------------------------------------------------------------
Professor Tejinder Singh Virdee: Imperial College London
Talk: Physics of the LHC, how they got to the LHC and how they built it.
Prof. Virdee acquired his graduate studies at Imperial College on an experiment conducted at the Stanford Linear Accelerator Centre, Stanford. Since 1979 he has worked on experiments at CERN such as the UA1 proton-antiproton collider experiment that discovered the mediators of the weak interaction, the W and Z bosons. He is one of the founders of the Compact Muon Solenoid (CMS) experiment at the LHC, also playing a crucial role in all phases of the CMS experiment. In a collaborative paper in 1990, Prof. Virdee outlined the two photons decay mode as being the most promising one for the search of a standard model (SM) Higgs boson in the low mass range. This work led to him pioneering the technique used in CMS’ electromagnetic calorimeter, namely lead tungstate scintillating crystals, that enables the precise measurement of the energies of the photons and electrons, crucial for the recent discovery of a new particle. From the official formation of CMS some 20 years ago to present day data-taking, his influence has extended well beyond calorimetry. He has been deeply involved in the analysis that has resulted in the ground-breaking discovery of the new boson. Within current precision the results obtained are consistent with expectations for a SM Higgs boson. Prof. Virdee was Deputy Leader from 1993 to 2006 and then Leader of the CMS Collaboration from 2007 to 2009.
Dr Ben Segal: CERN
Talk: Computing at CERN from Wim Klein to Tim Berners-Lee and beyond.
Dr Segal graduated in Physics & Mathematics at Imperial College London, first working for the UK Atomic Energy Authority then the Detroit Edison Company. He gained his Ph.D. in Mechanical & Nuclear Engineering from Stanford University and joined CERN in 1971 where he worked until his formal retirement in May 2002. He is now an Honorary staff member. His time at CERN was focussed on computer networking, including work on an early satellite data transmission system, "STELLA". He coordinated the introduction of Internet Protocols at CERN from 1983, paving the way for Tim Berners-Lee to invent the World Wide Web in 1989. He was also instrumental in developing "SHIFT", which changed the way computing is done, moving from mainframes to distributed Unix clusters, an important step in developing the Grid technology now used by the LHC. While at CERN he taught courses on Unix, distributed computing and Internet protocols in many places including China, India, Pakistan, Sri Lanka, Russia, Venezuela, Cuba, Italy and Sweden. Despite his retirement he is still involved with some projects especially in the area of "volunteer computing" and "volunteer thinking". These include LHC@home, Africa@home, the MalariaControl project and the Citizen Cyberscience Centre.
Professor John Ellis: Kings College London
Talk: Physics before and after the LHC and where will we go next?
Prof. Ellis attended the University of Cambridge, earning his Ph.D. in Theoretical Particle Physics in 1971. Before moving to CERN, he worked at the Stanford Linear Accelerator Complex and Caltech in the US. In 2010 he became the Clerk Maxwell Professor of Theoretical Physics at King's College London, while continuing his work at CERN. Throughout his career his work has been varied and has touched on many areas from Particle Physics and Astrophysics, to String Theory and Quantum Gravity. At CERN He has been both Deputy Division Leader and Division Leader for the theory division. He has written on the gluon, Higgs Boson, CP Violation, the Bottom Quark, Supersymmetry, Quantum Gravity and String Theory with his papers cited over 50,000 times. His work usually is close to experiment either by interpreting results or making prediction from theories that could be used in current or future experiments. He has been involved in investigating the physics possible with many accelerators including the LHC and its predecessor LEP. Currently he is part of the Physics Study Group for the Compact Linear Collider (CLIC), a possible future accelerator based at CERN.
Professor David Britton: University of Glasgow
Talk: The Grid, CERN's Supercomputer
Prof. Britton is a Professor of Physics at the University of Glasgow and Project Leader of the GridPP project that provides Grid computing for particle physics throughout the UK. He is a member of the ATLAS collaboration, one of the experiments at the Large Hadron Collider at CERN working on Higgs decays in association with a Z-boson. He is also a member of the NA62 collaboration that studies rare Kaon decays at CERN. Previously he worked on CMS, another of the LHC experiments, qualifying the crystals that make up the end-caps of the electromagnetic calorimeter. Earlier, he worked at the Stanford Linear Accelerator (the BaBar experiment); Cornell (the CLEO experiment); and at DESY in Hamburg (the ARGUS experiment) with an emphasis on tracking detectors. His PhD work at TRIUMF in Vancouver established the most stringent limits on Lepton Universality through rare pion decays and he is now part of the collaboration that is repeating the experiment to push the limits even further. He has been involved with the GridPP project since conception in 2000 and was one of the lead authors of the proposals for all three phases. Initially appointed as Project Manager, he took over as the GridPP Project leader in 2008. GridPP is a collaboration of Particle Physicists and Computing Scientists from 19 UK Universities together with the Rutherford-Appleton Laboratory and CERN, who have built a Grid for Particle Physics. As a leading partner in the worldwide LHC Computing Grid, GridPP was instrumental in enabling the discovery of the Higgs Boson.
Please note that catering is not included in the above ticket price.
at Theatre 4
Appleton Tower
Edinburgh, United Kingdom
Linking101.com.
Information And Tools For Webmasters To Improve Their Link Popularity Via Link Exchanges.
Ez-response Follow Up Sequential Auto Re
You Can Finally Send Unlimited Messages Without Cron Jobs!
No comments:
Post a Comment