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Standards Mapping

for Colorado 9-12

130

Standards in this Framework

45

Standards Mapped

34%

Mapped to Course

Standard Lessons
CS.HS.1.1a
Identify and create different types of algorithms (sort, search, etc.).
  1. 2.4 Functions in Karel
  2. 2.16 Karel Challenges
CS.HS.1.1b
Predict the outcome of different types of algorithms.
  1. 2.9 For Loops
  2. 2.11 If/Else Statements
  3. 2.12 While Loops in Karel
  4. 6.17 If/ Else Statements
  5. 6.18 While Loops
  6. 6.19 Putting Together Control Structures
CS.HS.1.1c
Create or adapt algorithms to solve problems for multiple purposes (e.g., personal interests, stakeholder needs).
  1. 2.6 Top Down Design and Decomposition in Karel
  2. 2.16 Karel Challenges
  3. 6.10 Top Down Design
  4. 6.19 Putting Together Control Structures
CS.HS.1.1d
Use an algorithm that involves mathematical operations and functions to solve problems.
  1. 2.9 For Loops
  2. 2.12 While Loops in Karel
  3. 2.16 Karel Challenges
  4. 3.4 Basic Math in JavaScript
  5. 6.17 If/ Else Statements
  6. 6.18 While Loops
  7. 6.19 Putting Together Control Structures
CS.HS.1.1e
Use an iterative approach to utilizing and/or developing an algorithm.
  1. 2.9 For Loops
  2. 2.12 While Loops in Karel
  3. 2.16 Karel Challenges
  4. 6.4 For Loops
  5. 6.14 Using i in For Loops
  6. 6.15 Extended Loop Control
  7. 6.18 While Loops
CS.HS.1.1f
Recognize problems that cannot be solved computationally.
CS.HS.1.1g
Identify and describe algorithms that exist within their personal lives.
  1. 2.6 Top Down Design and Decomposition in Karel
  2. 6.4 For Loops
  3. 6.10 Top Down Design
  4. 6.17 If/ Else Statements
CS.HS.1.2a
Illustrate the flow of execution of an iterative algorithm (e.g., recursion).
  1. 2.9 For Loops
  2. 2.12 While Loops in Karel
  3. 2.14 More Karel Examples and Testing
  4. 2.16 Karel Challenges
  5. 6.4 For Loops
  6. 6.14 Using i in For Loops
  7. 6.15 Extended Loop Control
  8. 6.18 While Loops
CS.HS.1.2b
Explain the value of heuristic algorithms to model ways to solve problems.
CS.HS.1.2c
Adapt algorithms used in one problem to solve a related or different problem.
  1. 2.4 Functions in Karel
  2. 2.16 Karel Challenges
CS.HS.1.2d
Use multiple methods to represent an algorithm (e.g., diagram, programming language, unplugged).
  1. 2.6 Top Down Design and Decomposition in Karel
  2. 2.14 More Karel Examples and Testing
  3. 6.10 Top Down Design
CS.HS.1.3a
Describe pros and cons of the performance of algorithms for the same task.
  1. 2.9 For Loops
  2. 6.4 For Loops
CS.HS.1.3b
Use an iterative approach to developing an algorithm.
  1. 2.6 Top Down Design and Decomposition in Karel
  2. 2.14 More Karel Examples and Testing
  3. 6.10 Top Down Design
CS.HS.1.3c
Test and troubleshoot so that algorithms produce reasonable results.
  1. 2.6 Top Down Design and Decomposition in Karel
  2. 2.16 Karel Challenges
  3. 6.18 While Loops
  4. 6.19 Putting Together Control Structures
CS.HS.1.4a
Demonstrate how the process of decomposition is iterative and used to solve problems.
  1. 2.6 Top Down Design and Decomposition in Karel
  2. 6.10 Top Down Design
CS.HS.1.4b
Formulate possible solutions based on the decomposition of a problem.
  1. 2.6 Top Down Design and Decomposition in Karel
  2. 6.10 Top Down Design
CS.HS.1.5a
Describe how abstraction is central to computational thinking.
  1. 2.8 Super Karel
CS.HS.1.5b
Identify and prioritize the most relevant parts of a problem while filtering out extraneous details.
  1. 2.6 Top Down Design and Decomposition in Karel
  2. 6.10 Top Down Design
CS.HS.1.5c
Demonstrate different ways to represent key problem components.
  1. 2.6 Top Down Design and Decomposition in Karel
  2. 2.16 Karel Challenges
  3. 6.10 Top Down Design
CS.HS.1.6a
Identify different types of data that are exchanged and produced by computers (e.g., protocols).
  1. 12.6 Packets and Protocols
  2. 13.6 Packets & Protocols
CS.HS.1.6b
Evaluate the trade-offs for how data elements are organized and where data are stored (e.g., PNG/GIF, structured/unstructured).
CS.HS.1.6c
Compare and contrast various data structures/techniques for storing and processing data (e.g., arrays, lists, tables).
CS.HS.1.7a
Provide multiple versions of data visualization in order to deepen problem analysis.
CS.HS.1.7b
Interpret and analyze data to make informed decisions.
CS.HS.1.8a
Analyze computer output in different forms (e.g., plain text, CSV, graphs, images).
CS.HS.1.8b
Design visualizations using the appropriate tool(s) with the end user in mind.
  1. 3.5 Using Graphics in JavaScript
  2. 6.9 Artistic Effects
  3. 6.12 User Input
  4. 6.17 If/ Else Statements
CS.HS.1.8c
Provide multiple versions of data visualization in order to deepen problem analysis.
CS.HS.2.1a
Describe key protocols and underlying processes of internet-based services, (e.g., https) and discuss impact of technology change on communication protocols.
  1. 1.13 Viewing Websites
  2. 12.3 Internet Addresses
  3. 12.4 DNS
  4. 12.5 Routing
  5. 12.6 Packets and Protocols
  6. 12.7 The Impact of the Internet
  7. 13.4 Domain Name System (DNS)
  8. 13.6 Packets & Protocols
CS.HS.2.1b
Illustrate and describe the basic components and various network types and topologies (e.g., personal, local, metropolitan, and wide).
  1. 12.2 Internet Hardware
CS.HS.2.1c
Explain the difference between decimal, hexadecimal, octal and binary number formats and how they are used in computing environments.
  1. 11.2 Number Systems
  2. 11.3 Encoding Text with Binary
  3. 11.4 Pixel Images
  4. 11.5 Hexadecimal
  5. 11.6 Pixel Colors!
  6. 11.7 Image Manipulation
CS.HS.2.2a
Explain the difference between memory and disk storage, internal and external storage, Random Access Memory (RAM), flash, cloud.
  1. 10.2 Computer Organization
  2. 12.2 Internet Hardware
CS.HS.2.2b
Explain how to maintain safety when working on PCs, e.g., electromagnetic precautions.
  1. 10.2 Computer Organization
CS.HS.2.2c
Describe how computing devices are engineered for fault tolerance and reliability, and identify potential sources of weakness (e.g., redundant power supplies, RAID, SAN/NAS connections).
  1. 12.5 Routing
  2. 13.5 Routing
CS.HS.2.3a
Identify and differentiate between different kinds of software (e.g., operating systems vs. applications) and their purposes.
  1. 10.3 Software
CS.HS.2.3b
Explain what an operating system is, and why it is important for a computer or computing device (e.g., Linux, Windows, iOS).
  1. 10.3 Software
CS.HS.2.3c
Describe how software interacts with hardware to complete tasks.
  1. 10.3 Software
  2. 10.4 Hardware
CS.HS.2.4a
Explain the integration of hardware, software and network communications components to create a networked system.
  1. 12.2 Internet Hardware
CS.HS.2.4b
Summarize security approaches using a systems approach perspective
  1. 13.7 Network Attacks
CS.HS.2.5a
Identify stakeholder’s problems/needs.
CS.HS.2.5b
Articulate design requirements back to stakeholder.
CS.HS.2.5c
Illustrate options for considerations and develop conceptual model.
CS.HS.2.5d
Perform system analysis based on stakeholder considerations.
CS.HS.2.6a
Describe elements of an effective backup system.
CS.HS.2.6b
Compare backup systems for computer users, or a network.
  1. 12.5 Routing
CS.HS.2.6c
List the various backup methodologies (e.g., full, differential), and why one would pick one over the other, or use all.
CS.HS.2.6d
Explain the ways an organization would continue to operate in light of a systems failure.
CS.HS.2.7a
Identify examples of threats to systems and data.
  1. 13.7 Network Attacks
CS.HS.2.7b
Describe the process by which intruders gain entry into a production system (e.g., reconnaissance).
CS.HS.2.7c
Describe and compare methods to test/validate how well systems and data are protected.
CS.HS.2.7d
Investigate different career pathways relating to systems security.
  1. 13.9 Impact of Cybersecurity
CS.HS.3.1a
Analyze and apply a design methodology to identify constraints and requirements of an identified problem.
CS.HS.3.1b
Utilize tools and resources such as pseudocode, flowcharts, wireframes, etc., as part of the design process.
  1. 2.6 Top Down Design and Decomposition in Karel
  2. 6.10 Top Down Design
CS.HS.3.1c
Determine and use graphical or text-based languages.
  1. 3.3 User Input
  2. 3.5 Using Graphics in JavaScript
  3. 6.1 Intro to Python with Tracy the Turtle
CS.HS.3.1d
Understand and apply core programming concepts.
  1. 2.9 For Loops
  2. 2.11 If/Else Statements
  3. 2.12 While Loops in Karel
  4. 3.2 Variables
  5. 6.4 For Loops
  6. 6.8 Functions
  7. 6.11 Variables
  8. 6.13 Parameters
  9. 6.16 If Statements
  10. 6.17 If/ Else Statements
  11. 6.18 While Loops
CS.HS.3.2a
Write code per selected design.
  1. 1.14 Project: Your First Website
  2. 6.10 Top Down Design
  3. 6.19 Putting Together Control Structures
CS.HS.3.2b
Create code comments to communicate to other developers and ensure documentation of code.
  1. 2.7 Commenting Your Code
  2. 6.6 Comments
CS.HS.3.2c
Use various troubleshooting and debugging techniques to improve code.
  1. 2.6 Top Down Design and Decomposition in Karel
  2. 2.7 Commenting Your Code
CS.HS.3.2d
Create appropriate variables to store and retrieve data.
  1. 3.2 Variables
  2. 6.11 Variables
CS.HS.3.3a
Integrate collaborative strategies to improve programming outputs.
CS.HS.3.3b
Identify and analyze a variety of collaborative tools (e.g., commenting, development repositories) in order to determine the appropriateness for intended use.
  1. 2.7 Commenting Your Code
CS.HS.3.3c
Identify strategies such as peer reviews to test and refine artifacts in development.
CS.HS.3.3d
Determine when to use standard software tools like APIs, libraries, version control repositories, etc.
  1. 2.8 Super Karel
  2. 3.5 Using Graphics in JavaScript
CS.HS.3.4a
Understand and apply principles of stakeholder-based design.
CS.HS.3.4b
Guide/advise stakeholders on strategies and solutions best suited for their problem (i.e., type of platform).
CS.HS.3.4c
Construct effective methods for gathering feedback from stakeholder.
CS.HS.3.4d
Respond to feedback from stakeholders to improve computing solutions.
CS.HS.3.4e
Create and share product support documentation for potential users.
CS.HS.3.4f
Articulate lessons learned as a result of the design and creation process.
  1. 1.14 Project: Your First Website
CS.HS.3.5a
Investigate and understand privacy, security and protection laws.
CS.HS.3.5b
Articulate the importance of securing personal data information on encrypted storage systems.
CS.HS.3.5c
Identify and analyze current events to ensure the safety, security and wellbeing of all potential stakeholders and end users.
CS.HS.3.5d
Identify influential computing innovations, and identify the beneficial and harmful effects they have had, or could have, on society, economy and culture.
  1. 12.7 The Impact of the Internet
CS.HS.3.5e
Discuss and explain how diversity of design and issues of accessibility impact a wide-range of users.
CS.HS.3.5f
Demonstrate ways to improve the accessibility of computational technologies and artifacts.
CS.HS.3.6a
Describe how software licensing influences program development.
CS.HS.3.6b
Investigate and develop solutions that discourage online software piracy.
CS.HS.3.6c
Explore and integrate security measures such as encryption, authentication and verification strategies to secure developed computer programs.
CS.HS.3.6d
Research and abide by intellectual property laws and patents.
  1. 12.7 The Impact of the Internet
CS.HS.4.1a
Define confidentiality, integrity and availability in the context of cybersecurity, and share a basic example of each.
CS.HS.4.1b
Analyze real-life scenarios to identify which of the core principles are at risk or have been compromised and explain why.
CS.HS.4.1c
Critically analyze case studies of cyber security incidents and identify where breaches in CIA have occurred.
CS.HS.4.1d
Research real-world examples of cyber security breaches and share their findings, focusing on how CIA principles were impacted.
CS.HS.4.2a
Compare and contrast applications based on their privacy policies and permissions, evaluating the impact on individuals and society.
CS.HS.4.2b
Synthesize understanding of privacy practices to inform peers on healthy vs harmful practices.
CS.HS.4.2c
Explain the individual risks of a data breach to an organization housing personal data. (Department of Homeland Security (DHS) through CISA Grant given to Cyber.org, 2021)
CS.HS.4.2d
Compare and contrast the harms and benefits between ensuring privacy and enabling convenience and usability (Dark, Daugherty, Emry, Massey, & Peyrot, 2021)
CS.HS.4.2e
Compare and contrast situations where one would want to be anonymous vs. identifiable and provide an example where one party desires anonymity but the other party desires clear identification.
CS.HS.4.2f
Discuss and/or give an example of how privacy decisions made today may have negative implications in the future.
CS.HS.4.2g
Describe one or more systems used on a regular basis which reveals information about a user’s pattern of life.
CS.HS.4.2h
Explain why trying every possible combination (a brute force attack) will always break encryption if given enough time.
CS.HS.4.2i
Describe ways encryption is used today.
CS.HS.4.2j
Evaluate strengths and weaknesses of an encryption method in context.
CS.HS.4.3a
Build a list of common threats students face and explain how an adversary may try to exploit those threats (adversarial thinking).
CS.HS.4.3b
Analyze real-life scenarios to identify which of the core principles are at risk or have been compromised and explain why. (This covers “Demonstrate adversarial thinking for a given problem. example: attack trees”)
CS.HS.4.3c
Explain how social behaviors and human factors can impact the cybersecurity of a system design. (Dark, Daugherty, Emry, Massey, & Peyrot, 2021)
CS.HS.4.3d
Evaluate digital habits and practices to identify potential risks and predict how an adversary might seek to exploit vulnerabilities.
CS.HS.4.3e
Analyze the motives of threat actors (Dark, Daugherty, Emry, Massey, & Peyrot, 2021)
CS.HS.4.3f
Explain the variety of ways in which a security vulnerability could be created and exploited (for example: system error, social engineering, or input by an adversary).
CS.HS.4.3g
Explain the difference between protecting against a random failure versus protecting against an intentional attack.
CS.HS.4.3h
Give an example of a system where the risk of a potential incident requires a high degree of security and an example where the risk of a potential compromise requires only a minor degree of security
CS.HS.5.1a
Explain the evolution of AI, the scope and limitations of current AI and the future of AI.
CS.HS.5.1b
Describe the purpose of different AI tools.
CS.HS.5.1c
Explain the potential ethical dilemmas and biases in developing, training, and using AI tools.
CS.HS.5.1d
Distinguish between AI and general computer programming.
CS.HS.5.1e
Describe real-world applications of AI, such as personal assistants, recommendation systems, advertising systems, and autonomous vehicles.
CS.HS.5.1f
Examine the differences between narrow AI and general AI, and their implications.
CS.HS.5.1g
Discuss the use of the term “learning” with respect to specific AI tools and techniques.
CS.HS.5.1h
Evaluate the kinds of data that can be used for AI problems and how they are used to train AI models.
CS.HS.5.1i
Evaluate, select and use appropriate AI technology to solve a problem.
CS.HS.5.2a
Develop and evaluate an AI-based solution to address a real-world objective.
CS.HS.5.2b
Describe how AI can create novel outcomes by identifying patterns in data from the domain of interest.
CS.HS.5.3a
Explain the potential limitations of AI; for example, insufficient or inaccurate data inputs, inability of the system to recognize its own errors, and flaws in the underlying algorithms.
CS.HS.5.3b
Evaluate the results produced by an AI tool before using it.
CS.HS.5.3c
Discuss challenges and considerations of AI with respect to personal privacy.
CS.HS.5.3d
Evaluate the implications of AI on job markets and its role in automation and productivity.
CS.HS.5.3e
Recognize the importance and challenges of human oversight in AI decision-making.
CS.HS.5.3f
Recognize the purpose and suitability of AI tools for achieving specific outcomes.
CS.HS.5.4a
Identify arguments regarding the dilemmas created by advances in artificial intelligence.
CS.HS.5.4b
Explain why computational artifacts can be attributed to an AI system rather than its initial programmers.
CS.HS.5.4c
Describe the "Turing Test" and its implications for distinguishing human and artificial intelligences.
CS.HS.5.4d
Articulate arguments against "artificial intelligence" qualifying as "actual intelligence" and counterarguments that refute those specific arguments.
CS.HS.6.1a
a. Describe how active and passive social media use can lead to positive and negative feelings.
CS.HS.6.1b
5 b. Identify research trends related to the health impact of screen time.
CS.HS.6.1c
6 c. Brainstorm strategies for navigating challenging relationships in a digital environment.
CS.HS.6.1d
8 d. Learn strategies for civil discourse in a digital environment and apply them to a scenario involving uncivil discourse.
CS.HS.6.1e
10 e. Define "digital reputation," and identify examples of social media posts that can have a positive or negative effect.
CS.HS.6.1f
12 f. Explain why you should ask permission before posting pictures or information about someone else.
CS.HS.6.1g
14 g. Identify strategies for protecting their privacy, including opting out of specific features and analyzing app or website privacy policies and terms of service.
CS.HS.6.1h
16 h. Define "misinformation" and explore the consequences of spreading misinformation online.
CS.HS.6.1i
18 i. Explore examples of confirmation bias, particularly related to news and online information.