GOOGLE _ DOODLE

Hi All,

               EPITOME OF CREATIVITY : THE GOOGLE DOODLE                             

Doodle History

Over the years, doodles on the Google homepage have made searching on Google more fun and enjoyable for its users worldwide. When doodles were first created, nobody had anticipated how popular and integral they would become to the Google search experience. Nowadays, many users excitedly anticipate the release of each new doodle and some even collect them!

In 1998, the concept of the doodle was born when Google founders Larry and Sergey played with the corporate logo to indicate their attendance at the Burning Man festival in the Nevada desert. A stick figure drawing was placed behind the 2nd "o" in the word, Google and the revised logo was intended as a comical message to Google users that the founders were “out of office.” While the first doodle was relatively simple, the idea of decorating the company logo to celebrate notable events was well received by our users.

A year later in 2000, Larry and Sergey asked current webmaster Dennis Hwang, an intern at the time, to produce a doodle for Bastille Day. Pleased with the result, Dennis was then appointed Google’s chief doodler and doodles became a regular occurrence on the Google homepage. In the beginning, the doodles tended to celebrate largely visible holidays; nowadays, doodles represent a wide array of events and anniversaries from the Winter Games to the Mars Rover landing.

How many doodles has Google done over the years?

The doodle team has created over 300 doodles for Google.com in the United States and over 700 have been designed internationally.

How can Google users/the public submit ideas for doodles?

The doodle team is open to user ideas; requests for doodles can be sent to proposals@google.com. The team receives numerous requests so even if we do not get back to you about your request, please know that we do look at and consider all the requests that are submitted.

Where can I see all the Google doodles that have been done over the years?

All doodles can be found at www.google.com/logos.

also visit :

http://www.google-logos.com/category/google-doodles

clariion Enclosure Types

Hi All ,
                                                           Enclosure Types

The above page diagrams the back-end structure of a Clariion. How the disks are laid out. Before we discuss the back-end bus structure, we should discuss the different types of enclosures that the Clariion contains.

1.DAE. The Disk Array Enclosure. Disk Array Enclosures exist in all Clariions. DAE’s are the enclosures that house the disks in the Clariion. Each DAE is holds fifteen (15) disks. The disks are in slots that are numbered 0 to 14.

2.DPE. The Disk Processor Enclosure. The Disk Processor Enclosure is in the Clariion Models CX300, CX400, CX500. The DPE is made up of two components. It contains the Storage Processors, and the first fifteen (15) disks of the Clariion.

3.SPE. The Storage Processor Enclosure. The Storage Processor Enclosure is in the Clariion Models CX700 and the CX-3 Series. The SPE is the enclosure that houses the Storage Processors.

The diagrams above lay out the DAE’s back-end bus structure. Data that leaves Cache and is written to disk, or data that is read from disk and placed into Cache travels along these back-end buses or loops. Some Clariions have one back-end bus/loop to get data from enclosure to enclosure. Others have two and four back-end buses/loops to push and pull data from the disks. The more buses/loops, the more expected throughput for data on the back-end of the Clariion.

The Clariion Model on the left is a diagram of a CX300/CX3-10 and CX3-20. These models have a single back-end bus/loop to connect all of the enclosures. The CX300 will have one back-end bus/loop running at a speed of 2 GB/sec, while the CX3-Series Clariions have the ability to run up to 4 GB/sec on the back-end.

The Clariion Model in the middle is a diagram of a CX500. The CX500 has two back-end buses/loops. This gives the CX500, twice the amount of potential throughput for I/Os than the CX300.

The Clariion Model on the right is a diagram of a CX700, CX3-40 and CX3-80. These Clariions contain four back-end buses/loops. The CX3-80 will contain the maximum back-end throughput with all four buses having the ability to run at a 4 GB/sec speed.

Each enclosure has a redundant connection for the bus that it is connected. This is in the event that the Clariion loses a Link Control Card (LCC) that allow the enclosures to move data, or the loss of a Storage Processor. You will see one bus cabled out of SP A and SP B, allowing both SP’s access to each enclosure.

Enclosure Addresses

To determine an address of an enclosure, we need to know two things, what bus it is on, and what number enclosure it is on that bus. On the Clariions in the left diagram, there is only one back-end bus/loop. Every enclosure on these Clariions will be on Bus 0. The enclosure numbers start at zero (0) for the first enclosure and work their way up. On these Clariions, the first enclosure of disks is labeled Bus 0_Enclosure 0 (0_0). The next enclosure of disks is going to be Bus 0_Enclosure 1 (0_1). The next enclosure of disks 0_2, and so on.

The CX500, with two back-end buses will alternate enclosures with the buses. The first enclosure of disks will be the same as the Clariions on the left of Bus 0_Enclosure 0 (0_0). The next enclosure of disks will utilize the other back-end bus/loop, Bus 1. This enclosure is Bus 1_Enclosure 0 (1_0). It is Enclosure 0, because it is the first enclosure of disks on Bus 1. The third enclosure of disks is going to be back on Bus 0, 0_1. The next one up is on Bus 1, 1_1. The enclosures will continue to alternate until the Clariion has all of the supported enclosures. You might ask why it is cabled this way, alternating buses. The reason being is that most companies don’t purchase Clariions fully populated. Most companies buy disks on an as needed basis. By alternating enclosures, you are using all of the back-end resources available for that Clariion.

The Clariions on the right show the four bus structure. The first enclosure of disks is going to be Bus 0_Enclosure 0 (0_0) as all other Clariions. The next enclosure of disks is Bus 1_Enclosure 0 (1_0). Again, using the next available back-end bus, and being the first enclosure of disks on that bus. The third DAE is going to be Bus 2_Enclosure 0 (2_0). The fourth DAE is on the fourth and last back-end bus. It is Bus 3_Enclosure 0 (3_0). From here, we are back to Bus 0 for the next enclosure of disks. Bus 0_Enclosure 1 (0_1). The next DAE is 1_1. The next would be 2_1 if we had one. 3_1, 0_2, and so on until the Clariions were fully populated.

Disk Address

The last topic for this page are the disks themselves. To find a specific disk’s address, we use the Enclosure Address and add the Slot number the disk is in. This gives us the address that is called the B_E_D. Bus_Enclosure_Disk. The Clariion on the left has a disk in slot number 13. The address of that disk would be 0_2_13. The Clariion in the middle has a disk in slot number 10 of Enclosure 1_1. This disk address would be 1_1_10. And the Clariion on the right has a disk in Bus 2_Enclosure 0. It’s address is 2_0_6. And the disk in Bus 1_Enclosure 1 is in slot 9. Address = 1_1_9.

Finally, each Clariion has a limit to the number of disks that it will support. The chart below the diagrams provides the number of how many disks each model can contain. The CX300 can have a maximum of 60 disks, whereas the CX3-80 can have up to 480 disks.

The importance of this page is to know where the disks live in the back of the Clariion in the event of disk failures, and more importantly how you are going to lay out the disks. Meaning, what applications on going to be on certain disks. In order to put that data onto disks, we have to create LUNs (will get to it), which are carved out of RAID Groups (again, getting there shortly). RAID Groups are a grouping of disks. To have a nice balance and to achieve as much performance and throughput on the Clariion, we have to know how the Clariion labels the disks and how the DAE’s are structured.

EMC DMX, DMX2: Model numbers, basic differences, 3 Phase, Single Phase, Drive counts, Drives per loop

Hi All,

The basic differences on DMX and DMX2 machines. Based on some data I had put together, here are the major differences on a DMXxxxx vs a DMX-P2 vs a DMX-M2-3, etc. 

The number of drives per loop: the lesser the drives on a single loop the better the performance. There are two different versions of drives per loop: one being the 9 drives per loop and the other one being 18 drives per loop.

Following are all 18 drives per loop

DMX1000:   

Low Performance,
1st Generation DMX,
18 drives per loop,
Single Bay with Single Phase power,
144 drives max. 

DMX1000-M2:        
High Performance,
2nd Generation DMX,
18 drives per loop,
Single Bay with Single Phase power,
144 drives max.

DMX2000:              
Low Performance,
1st Generation DMX,
18 drives per loop,
Dual Bay with Single Phase power,
288 drives max. 

DMX2000-M2:        
High Performance,
2nd Generation DMX,
18 drives per loop,
Dual Bay with Single Phase power,
288 drives max.

DMX2000-M2-3:     
High Performance,
2nd Generation DMX,
18 drives per loop,
Dual Bay with Three Phase power,
288 drives max. 

DMX3000-3:           
Low Performance,
1st Generation DMX,
18 drives per loop,
Triple Bay with Three Phase power,
576 drives max . 

DMX3000-M2-3:     
High Performance,
2nd Generation DMX,
18 drives per loop,
Triple Bay with Three Phase power,
576 drives max.

Following are all 9 drives per loop

DMX1000-P:           
Ultra Performance, 1st Generation DMX,
9 drives per loop,
Single Bay with Single Phase power,
144 drives max. 

DMX1000-P2:         
Ultra Performance,
2nd Generation DMX,
9 drives per loop,
Single Bay with Single Phase power,
144 drives max.

DMX2000-P:           
Ultra Performance,
1st Generation DMX,
9 drives per loop,
Dual Bay with Single Phase power,
288 drives max.

DMX2000-P2:         
Ultra Performance,
2nd Generation DMX,
9 drives per loop,
Dual Bay with Single Phase power,
288 drives max. 

DMX2000-P2-3:      
Ultra Performance,
2nd Generation DMX,
9 drives per loop,
Dual Bay with Three Phase power,
288 drives max. 

Machines are categorized as a DMX and DMX2,DMX3,DMX4 The ones above with a P2 or M2 are DMX2. 

The new generation of DMX machine’s now available in the market are: DMX-3 and DMX-4. the latest one is VMAX it supports flashdrives also.