A utility company’s website is attacked by a botnet, a program built specifically to replicate malicious software on the Web. It was spreading rapidly online by injecting itself into vulnerable websites and then waiting for unsuspecting users to click on the site. When they did, the code copied itself on their computers. In a few months, 360,000 sites had been infected. The botnet was diabolically engineered to sniff out the Achilles heel in SQL. The botnet co-opted an application on the company Website and injected itself directly into a company database. The fear was that in the process, it could get past the utility’s larger security perimeter and have its way with the company’s software portfolio of applications, database tools and other code. It also had the potential to install itself on the computers of anyone who visited the utility’s website. The attack was a legitimate risk to the utility company.
The utility knew it wanted (needed) a new culture for how it engineered, developed and tested its software. It also knew it wanted that culture grounded in widely accepted standards. That way, coders could learn from one another, and the company would not be re-inventing its cultural wheel to make its software more secure. The catch was, no one on staff knew much about how to make applications safer.
The design phase of the cyber security development lifecycle (CSDL) requires developers to create something called a cyber threat model. That is, a sense of the cyber attacks an application might face. What kind of exploits might a cyber attacker use? How would hackers gain access to an application running on a computer network? What older, existing pieces of code associated with the new application might be vulnerable? This overall feel for the risks an application might come under allows coders to anticipate risks. Threat models need not be complex: Even high-quality ones can be done on the back of cocktail napkins.
Once the standard was set, critical areas were addressed and basic training was completed, next up was spreading the new cyber security culture inside the utility. Two basic lines of work emerged: remediation on the existing code where needed, and maximizing the cyber security of all new code created from that point on. The company-wide remediation was a copy of the early, high-level work on the website: carefully anticipating threats identified by the utility‘s version of CSDL, analyzing each threat and then refactoring code where necessary. This strategic work was buttressed by scanning tools that helped identify high, medium and low risks. But, despite this automatic assistance, it was immediately clear the work ahead would not be easy.
Time was something the utility’s coders had little of. Its IT department was designed to be an internal resource for the coding needs of various departments: providing the company’s energy traders with a new way to manage their inventory, helping human resources manage employee benefits, and planning how utilities route their electricity or gas. But, under a mandate from the top, they found a way. And, slowly, cyber software security at the utility moved from afterthought to top-of-mind. Under CSDL, the utility now started with cyber security. Step one in the process was identifying a well-thought-out set of cyber threats that showed where a piece of software might be weak. How would the code be used? What was at risk? Then, using its new test tools and protocols, the entire development team became responsible for keeping the code within the standard. The utility had even gone so far as to install a last step — a human review to triple check that all new code cleared the cyber security bar before it went live.
1.What does the design phase of the cyber security development lifecycle (CSDL) require developers to create?
2. Once the standard was set (critical areas were addressed and basic training was completed; next up was spreading the new cyber security culture inside the utility), what were the two basic lines of work that emerged?
3.Why is cyber security not an absolute?
Topic: Cyber Security Development Lifecycle
Link to Presentation: http://booksite.elsevier.com/9780123918550/casestudies/Chapter_04.html
Name 3 Ways
Paper Organization (300pts)
Use Times New Roman 12 font and double spaced. Ensure you are familiar with current APA guidelines as it relates to writing research paper.
Cover page (Use sample paper as a guide) (10pts)
Need introduction paragraph with thesis statement (50pts)
Three different paragraphs with each practice (90pts)
Concluding paragraph (50pts)
Reference page (50pts)
Follow APA Guidelines (50pts)
5 to 6 pages total
PPT Presentation (About 30 minutes Long; 200pts)
Wear Business Attire (10pts)
Slide 1-Cover page with title (10pts)
Slide 2– Group Names
Slide 3- Table of content (5 pts)
Slide 4-Introduction (20pts)
Slide 5-Thesis statement (20pts)
Slides 6, 7, and 8- Different ideas in different paragraphs (75pts)
Slide 9-Summary (20pts)
Slide 10-References (40pts)
You have to be 100% sure of the quality of your product to give a money-back guarantee. This describes us perfectly. Make sure that this guarantee is totally transparent.
Read moreEach paper is composed from scratch, according to your instructions. It is then checked by our plagiarism-detection software. There is no gap where plagiarism could squeeze in.
Read moreThanks to our free revisions, there is no way for you to be unsatisfied. We will work on your paper until you are completely happy with the result.
Read moreYour email is safe, as we store it according to international data protection rules. Your bank details are secure, as we use only reliable payment systems.
Read moreBy sending us your money, you buy the service we provide. Check out our terms and conditions if you prefer business talks to be laid out in official language.
Read more