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Build Supercomputers with Raspberry Pi 3

You're reading from   Build Supercomputers with Raspberry Pi 3 A step-by-step guide that will enhance your skills in creating powerful systems to solve complex issues

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Product type Paperback
Published in Mar 2017
Publisher Packt
ISBN-13 9781787282582
Length 254 pages
Edition 1st Edition
Languages
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Author (1):
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Carlos R. Morrison Carlos R. Morrison
Author Profile Icon Carlos R. Morrison
Carlos R. Morrison
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Table of Contents (13) Chapters Close

Preface 1. Getting Started with Supercomputing FREE CHAPTER 2. One Node Supercomputing 3. Preparing the Initial Two Nodes 4. Static IP Address and Hosts File Setup 5. Creating a Common User for All Nodes 6. Creating a Mountable Drive on the Master Node 7. Configuring the Eight Nodes 8. Testing the Super Cluster 9. Real-World Math Application 10. Real-World Physics Application 11. Real-World Engineering Application A. Appendix

Additional analytical perspective

Another perspective on why we need more computing power, goes as follows: let us supposed we want to predict the weather over an area covering the United States, and Canada. We cover the region with a cubical grid that extends 20 km over sea level, and examine the weather at each vertex of the grid. Now, suppose we use a cubic component of the grid that is 0.1 kilometer on the sides, and since the area of the United States, and Canada is approximately 20 million square kilometers. We therefore would need at least Additional analytical perspective  let us also assume we need a minimum of 100 calculations to ascertain the weather condition at a grid point, then the weather, one hour hence, will require Additional analytical perspective  calculations. Now, to predict the weather hourly for the next 48 hours, we will need Additional analytical perspective. Assuming our serial computer can processAdditional analytical perspective (one billion) calculations per second, it will take approximately Additional analytical perspective. Clearly, this is not going to work to our benefit if the computer is going to predict the weather at a grid point in 23 days. Now, suppose we can flip a switch that turbocharges our computer to perform Additional analytical perspective  (1 trillion) calculations per second; it would now take approximately half an hour to determine the weather at a grid point, and the weather guy can now make a complete prediction in the next 48 hours. 

Outside of weather prediction, there are numerous other conditions/events occurring in the real world/universe that require a higher rate of calculation. This would require our computer to have a much higher processing speed in order to solve a given problem in a reasonable time. It is this nettling fact that is driving engineers and scientist to pursue higher and higher computational power. This is where parallel computing/supercomputing, with its associated MPI codes, excels. However, obstacles to widespread adaption of parallelism abound, courtesy of the usual suspects: hardware, algorithms, and software.

With regards to hardware, the network intercommunication pathway, aka switches, are falling behind the technology of the modern processor, in terms of communication speed. Slow switches negatively impact the theoretical upper computational speed limit of a supercomputer. You will observe this phenomenon when running your Pi supercomputer, as you bring successive nodes online that transition the input ports on the HP switch. Switch technology is improving, though not fast enough.

Processing speed is dependent on how fast a parallel code executes on the hardware, hence software engineers are designing faster and more efficient parallel algorithms that will boost the speed of supercomputing. Faster algorithms will boost the popularity of parallelism.

Finally, the most impactful obstacle to widespread adoption of parallelism is inadequate software. To date, compilers that can automatically parallelize sequential algorithms are limited in their applicability, and programmers are resigned to providing their own parallel algorithm.

You have been reading a chapter from
Build Supercomputers with Raspberry Pi 3
Published in: Mar 2017
Publisher: Packt
ISBN-13: 9781787282582
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