June 17th, 2009 by comptia in cisco · No Comments
Here is an updated video (in two parts) in which Pierre, one of our TMEs takes you through an in-depth tour of the Cisco Nexus 1000V including config, port profiles and VMotion in action. If these entice you to want to play, head on over to cisco.com/go/1000veval for fully functioning eval copy (free CCO reg required, eval is good for 60 days and 16 CPUs).
NOTE: The videos are in HD so you can see screen detail in vCenter and the Nexus 1000V console etc, so you’ll get your best viewing experience by clicking through to our Cisco DC Facebook page and watching full screen—also bring popcorn.
more cisco exam dumps visit http://www.testpassport.com/Cisco/
June 17th, 2009 by comptia in cisco · No Comments
Q. What is smart grid?
A. Smart grid is the term generally used to describe the integration of all elements connected to the electrical grid
with an information infrastructure, offering numerous benefits for both the providers and consumers of electricity.
Smart grid can be considered an intelligent future electricity system that connects all supply, grid, and demand
elements through an intelligent communication system. The backbone of a successful smart-grid operation is a
reliable, resilient, highly secure, and manageable standards-based, open communication infrastructure that
intelligently links the elements of the grid while participating in the decision making that delivers value to the
utility and supply and demand entities connected to it.
Q. What is the current state of power distribution and management?
A. Much of today’s systems are one-way. Power is generated and distributed through the utility (or leased)
transmission and distribution lines, and either consumed or not. There is no storage capability, so power-
generating facilities need to have excess capacity in order to meet peak demands, or consumers experience
service disruptions. Feedback on energy consumption is limited, and consumers may or may not have access to
current energy consumption (demand) and pricing considerations.
In short, much of today’s electrical generation capability is one-way: Produce as much as you think you need to
meet the peak demand without any feedback, but make sure you have enough so the consumer does not go
without.
Q. What are the concerns and inefficiencies in today’s approach?
A.
● Energy consumption is rising and is anticipated to rise even more as consumers use more energy-consuming
devices (imagine a plug-in hybrid vehicle in every garage that gets plugged in to recharge every night at 9
p.m.) The generating utility must meet anticipated peak demand.
● Consumers are exploring alternate sources of energy (wind, solar, etc.) and may be able to give excess power
back to their utility, or could significantly reduce their consumption, complicating the forecasting ability of the
utility while raising pricing concerns for both the utility and the consumer.
● The utility must begin to anticipate these new sources of energy as well as the questions related to them.
● Base energy costs to generate electricity are rising or in some cases inconsistent, complicating the forecasting
task for many utility companies.
● Regulations from respective governments may complicate emissions, allowable price to the consumer, etc.
● In simplest terms, the generating facility lacks visibility to the end devices and consumption across its grid and
suffers operational inefficiency, leading to potentially higher costs as well as inability to supply.
● Utilities are also deploying a variety of “smart sensors” or intelligent end devices (such as programmable
thermostats) to help them sense and manage demand. These intelligent sensors present a communications
need to the utilities that often does not presently exist. Many utilities are also installing or contemplating the
installation of automated meter reading, both to provide more accurate real-time data and to reduce the cost
of manually reading meters. However, in many cases there is no communications infrastructure to get this
data back to an operations center
Q. What are the various nodes in the power network?
A. Power utilities have some sort of generating facility where raw fuel is converted to electricity. A transmission line
and associated substation carries the electricity from the generating location out to be consumed. A distribution
network breaks down the high-voltage electricity for consumption by consumers, commercial buildings, and
manufacturing facilities. Inside each of these consuming locations is some sort of feeder box that provides local
control of the electricity.
A variety of communications occurs between these places—including Ethernet, wired serial communications,
and wireless. Sometimes they are based on proprietary networks, sometimes open. In some cases an existing
Supervisory Control and Data Acquisition (SCADA) system exists through part of the grid management system.
In some cases an existing distributed control system (DCS) controls part of the existing grid.
Q. What are the benefits of smart grid to different stakeholders?
A. Smart grid offers the utility and the consumer bidirectional communication and visibility to better control electricity
supply and demand as well as the cost associated with it. Both consumers and utilities will be better able to
manage their energy costs, and future expansion of the “grid” to allow new capabilities will be enhanced.
Q. What components are needed to deliver a smart grid? What are the gaps and opportunities?
A. A secure, integrated communications network from the generating station to the end device is critical. Providing
secure communication among all the various entities that may exist (or may not, depending on the local
regulatory and utility operation) is also a critical component of any solution for smart grid.
This scenario translates to secure Ethernet switching and routing, secure wireless, secure access to meter
reading, secure access to end devices in the home or business, trust between the consumer and the utility,
secure unified communications between the utility and remote workers or facilities, and potentially intelligent
messaging to the consumer or remote workers—in other words, everything that Cisco does well today.
Q. What is Cisco’s vision and strategy for smart grid?
A. In many ways we see this scenario as analogous to the birth of the Internet. Islands of operations are spread
throughout the “grid” area. These islands may be (and include) the generating facility, the transmissions
substation, the distribution substation, the home, the commercial building, the manufacturing plant, and the
network operations center (perhaps multiple centers per utility).
We see our opportunity as one of providing intelligent, transparent communication infrastructure between these
various entities. The infrastructure includes unified communications between workers and facilities, extending
into the home or commercial building to enhance their ability to control energy usage as well as enhance their
communications and control through an integrated network, and securing the entire enterprise with Cisco
security products.
We see an opportunity to provide thought leadership to all of the entities involved, whether they be utility,
consumer, business manager, industrial plant manager, or others.
This architecture will take the form of a proven documentable and replicable architecture on which to securely
build a smart grid that will remain secure as capacity is added.
Our plan is to build a Cisco Validated Design for Smart Grid that is replicable and proven.
Q. Why is Cisco relevant in this market? What is Cisco’s value add?
A. Cisco is the world’s leading supplier of communications products that have led the development of the Internet.
The communication needs of the utility industry are similar to the challenges that our expertise and solutions
have helped overcome in the past, working in concert with customers and partners to develop a solution that
grows over time.
Cisco is very well-known in the enterprise, meaning that business customers know us as a valued supplier, and
we continue to grow in the home and business sectors.
Cisco is well-positioned to provide an end-to-end solution. We have demonstrated the ability to work with
important partners to accelerate solutions geared to customer needs, combining the best of the best to provide
highly secure, integrated solutions.
June 17th, 2009 by comptia in cisco · No Comments
VPN or virtual private network technology allows you to securely connect remote offices and remote users using cost-effective, third-party Internet access.
A VPN provides the highest possible level of security through encryption and authentication technologies that protect data traversing the VPN from unauthorized access.
You can take advantage of the easy-to-provision Internet infrastructure to quickly add new sites or users, dramatically increasing the reach of your networks without significantly expanding infrastructure.
VPN Technologies Offer Choices
Two VPN technologies, Secure Sockets Layer (SSL) and IP Security (IPsec), have become the primary solutions for connecting remote offices, remote users, and business partners, because they:
- Provide highly secure communications with access rights tailored to individual users
- Enhance productivity by extending corporate networks, applications, and collaboration tools
- Reduce communications costs while increasing flexibility
The two types of encrypted VPNs are:
- Site-to-Site IPsec VPN: This alternative to frame relay or leased-line WANs allows you to extend your network resources to branch offices, home offices, and business partner sites.
- Remote Access VPN: This type of VPN extends almost any data, voice, or video application to the remote desktop, emulating the main office desktop.
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