Informatic fundamentals

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Word Processing Assignment

This assignment is designed to check your word processing skills that specifically relate to formatting and proofing a document. You will start with the text as it is provided to you in the text file and apply the steps outlined in these instructions and submit the revised document to your instructor for review and grading.

If you need help in performing any of the instruction steps, you can use the Help feature that is built into Microsoft Word or you can use the step-by-step guides with pictures that can be found at:

There are several tools available on this web page to assist you with performing the steps required in this assignment. You can select specific tools depending on what version of Microsoft Word you are using on your local computer. If you are already familiar with Microsoft Word this assignment should take less than 15 minutes to complete. If you are relatively new to Word and have to research how to perform many of the steps, this activity may take 1-2 hours to complete.

If you are using Google Docs, then you can find word processing support at:

Have fun!

File as presented: sampletext.docx

Font: Arial Black

Size: 10 pt

Spacing: single-spaced

File to be submitted: INFM_109_YourLastName.docx (where you replace YourLastName with your actual last name)

Font: Times New Roman

Size: Assorted, see detailed instructions below

Spacing: 1.5 line spacing


Using the sampletext.docx file as your starting point, complete the following formatting in this order:

1. Change the font in the entire document to Times New Roman

2. Take the first sentence in the first paragraph (What is a quantum computer?) and use it as the title line at the very top of the document. Set the Style of the title to Heading 1 and make sure it is centered.

3. Format the main body of the document to Times New Roman, 12 pt, and line spacing of 1.5

4. Cut the section of the document that begins with “What is entanglement?” and ends just before “What is a qubit?”and place it directly before the section that begins with “What is decoherence?”

5. Break the following sentences out as section headings and format them all in Heading 3 style, justified to the left:

a. What is a qubit?

b. What is superposition?

c. What is entanglement?

d. What is decoherence?

e. What is quantum supremacy?

f. Where is a quantum computer likely to be most useful first?

6. Next, you are going to create a bullet list after paragraph two. Leaving the last paragraph intact, insert a copy of the last paragraph immediately after paragraph two and convert the items following the colon into a bullet list.

7. Change the line spacing between the items on the bullet list that you just created in Step 6 to single space

8. In the sentence at the beginning of the document that starts with,“A quantum computer harnesses…” Create a hyperlink for the text “quantum computer” and link it to:

9. Using the Insert tab, add page numbers at the bottom of the page in the right corner using Plain Number 3 style

10. Add a header and put your name in the header

11. Insert page breaks at the following locations:

a. After the first paragraph in the “What is a qubit” section

b. After the first paragraph in the “What is entanglement” section

12. On the Review tab, check for and correct all spelling and grammar errors.NOTE: Rigetti and IonQ are spelled correctly. Keep running through the correction checker, making corrections as necessary, until there are zero errors

13. Manually scan back over the entire document. At this point there should be no words underlined with red or blue

14. If you see any lines where the text is stretched out to fit across the page, adjust the spacing after the end of the period in that sentence

Turn on “Show/Hide” so that all of formatting symbols are displayed

16. Save the file using “Save As” and change the file name to INFM_109_YourLastName and use the .docx file name extension, replacing YourLastName with your actual last name.

17. Submit the assignment for review and grading by the instructor.

What is a quantum computer?A quantum computer harnesses some of the almost-mystical phenomena of quantum mechanics to deliver huge leaps forward in processing power. Quantum machines promise to outstrip even the most capable of today’s—and tomorrow’s—supercomputers.

They won’t wipe out conventional computers, though. Using a classical machine will still be the easiest and most economical solution for tackling most problems. But quantum computers promise to power exciting advances in various fields, from materials science to pharmacuticals research. Companies are already experimenting with them to develop things like lighter and more powerful batteries for electric cars, and to help create novel drugs.

The secret to a quantum computer’s power lies in its ability to generate and manipulate quantum bits, or qubits. 

What is entanglement? Researchers can generate pairs of qubits that are “entangled,” which means the two members of a pair exist in a single quantum state. Changing the state of one of the qubits will instantaneously change the state of the other one in a predictable way. This happens even if they are separated by very long distances.

Nobody really knows quite how or why entanglement works. It even baffled Einstein, who famously described it as “spooky action at a distance.” But it’s key to the power of quantum computers. In a conventional computer, doubling the nmber of bits doubles its processing power. But thanks to entanglement, adding extra qubits to a quantum machine produces an exponential increase in its number-crunching ability.

Quantum computers harness entangled qubits in a kind of quantum daisy chain to work their magic. The machines’ ability to speed up calculations using specially designed quantum algorithms is why there’s so much buzz about their potential.

That’s the good news. The bad news is that quantum machines are way more error-prone than classical computers because of decoherence. 

What is a qubit? Today’s computers use bits—a stream of electrical or optical pulses representing 
1s or 
0s. Everything from your tweets and e-mails to your iTunes songs and YouTube videos are essentially long strings of these binary digits.

Quantum computers, on the other hand, use qubits, which are typically subatomic particles such as electrons or photons. Generating and managing qubits is a scientific and engineering challenge. Some companies, such as IBM, Google, and Rigetti Computing, use superconducting circuits cooled to temperatures colder than deep space. Others, like IonQ, trap individual atoms in electromagnetic fields on a silicon chip in ultra-high-vacuum chambers. In both cases, the goal is to isolate the qubits in a controlled quantum state.

Qubits have some quirky quantum properties that mean a connected group of them can provide way more processing power than the same number of binary bits. One of those properties is known as superposition and another is called entanglement. 

What is superposition? Qubits can represent numerous possible combinations of 
at the same time. This ability to simultaneously be in multiple states is called superposition. To put qubits into superposition, researchers manipulate them using precision lasers or microwave beems.Thanks to this counterintuitive phenomenon, a quantum computer with several qubits in superposition can crunch through a vast number of potential outcomes simultaneously. The final result of a calculation emerges only once the qubits are measured, which immediately causes their quantum state to “collapse” to either 

What is decoherence? The interaction of qubits with their environment in ways that cause their quantum behavior to decay and ultimately disappear is called decoherence. Their quantum state is extremely fragile. The slightest vibration or change in temperature—disturbances known as “noise” in quantum-speak—can cause them to tumble out of superposition before their job has been properly done. That’s why researchers do their best to protect qubits from the outside world in those supercooled fridges and vacuum chambers.

But despite there efforts, noise still causes lots of errors to creep into calculations. 
Smart quantum algorithms can compensate for some of these, and adding more qubits also helps. However, it will likely take thousands of standard qubits to create a single, highly reliable one, known as a “logical” qubit. This will sap a lot of a quantum computer’s computational capacity.

And there’s the rub: so far, researchers haven’t been able to generate more than 128 standard qubits (see our qubit counter 
here). So we’re still many years away from getting quantum computers that will be broadly useful.

That hasn’t dented pioneers’ hopes of being the first to demonstrate “quantum supremacy.”

What is quantum supremacy?It’s the point at which a quantum computer can complete a mathematical calculation that is demonstrably beyond the reach of even the most powerful supercomputer.

It’s still unclear exactly how many qubits will be needed to achieve this because researchers keep finding new algorithms to boost the performance of classical machines, and supercomputing hardware keeps getting better.But researchers and companies are working hard to claim the title, 
running tests against some of the world’s most powerful supercoputers.

There’s plenty of debate in the research world about 
just how significant achieving this milestone will be. Rather than wait for supremacy to be declared, companies are already starting to experiment with quantum computers made by companies like IBM, Rigetti, and D-Wave, a Canadian firm. Chinese firms like Alibaba are also offering access to quantum machines. Some businesses are buying quantum computers, while others are using ones made available 
through cloud computing services.

Where is a quantum computer likely to be most useful first?One of the most promising applications of quantum computers is for 
simulating the behavior of matter down to the molecular level. Auto manufacturers like Volkswagen and Daimler are using quantum computers to simulate the chemical composition of electrical-vehicle batteries to help find new ways to improve their performance. And pharmaceutical companies are leveraging them to analyze and compare compounds that could lead to the creation of new drugs.

The machines are also great for optimization problems because they can crunch through vast numbers of potential solutions extremely fast. Airbus, for instance, is using them to help calculate the most fuel-efficient ascent and descent paths for aircraft. And Volkswagen has unveiled a service that calculates the optimal routes for buses and taxis in cities in order to minimize congestion. Some researchers also think the machines could be used 
to accelerate artificial intelligence.

It could take quite a few years for quantum computers to achieve their full potential. Universities and businesses working on them are facing 
a shortage of skilled researchers in the field—and 
a lack of suppliers of some key components. But if these exotic new computing machines live up to their promise, they could transform entire industries and turbocharge global innovation.

Key differences between conventional and quantum computers include: Conventional computers store and manipulate data based on a bit that is based on an electrical change and has one of two values, 0 or 1. Quantum computers store and manipulate data using a qubit that is based on the spin of an electron and has more than two possible values. Conventional computers are governed by the rules of classic physics. Quantum computers are governed by quantum physics or quantum mechanics.

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