Programming: Difference between revisions

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[[file:computation.png|right|frame|Computational thinking, problem-solving and programming<ref>http://www.flaticon.com/</ref>]]
[[file:computation.png|right|frame|Programming<ref>http://www.flaticon.com/</ref>]]


When you are programming a computer you use common constructions. Please remember every computer programming language approaches '''syntax''' differently. All programming languages share common features, below:


=== Thinking procedurally ===


* [[Procedural thinking]]
== Use of programming languages ==
* [[Evaluating process]]
* [[Sub-process]]
 
=== Thinking logically ===
 
* [[Logical decisions]]
* [[Conditions and decisions]]
* [[Logical rules]]
 
=== Thinking ahead ===
 
* [[Inputs and outputs]]
* [[Pre-conditions]]
* [[Exceptions and pre-conditions]]
 
=== Thinking concurrently ===
 
* [[Concurrency]]
 
=== Thinking abstractly ===
 
* [[Abstraction]]
* [[Applied abstraction]]
 
=== Connecting computational thinking and program design  ===
 
* [[Linear arrays]]
* [[Pseudocode]]
* [[Algorithms]]
* [[Applied algorithmic thinking]]
 
=== Introduction to programming ===
 
* [[What is a programming language?]]
* [[High level languages]]
* [[Compiler]]
* [[Low level languages]]
* [[Translating high-level code to low-level code]]
* [[Control flow]]
 
=== Use of programming languages ===  


* [[Variables]]  
* [[Variables]]  

Revision as of 13:09, 14 July 2017

Exclamation.png This is one of the most important ideas you can remember:

Decompose a problem into smaller parts, model a problem with flowcharts. Learn to think sequentially

Programming[1]

When you are programming a computer you use common constructions. Please remember every computer programming language approaches syntax differently. All programming languages share common features, below:


Use of programming languages[edit]

Other important ideas in programming[edit]

Standards[edit]

Computational thinking, problem-solving and programming
Identify the procedure appropriate to solving a problem. Computational Thinking
Evaluate whether the order in which activities are undertaken will result in the required outcome. Computational Thinking
Explain the role of sub-procedures in solving a problem. Computational Thinking
Identify when decision-making is required in a specified situation. Computational Thinking
Identify the decisions required for the solution to a specified problem. Computational Thinking
Identify the condition associated with a given decision in a specified problem. Computational Thinking
Explain the relationship between the decisions and conditions of a system. Computational Thinking
Deduce logical rules for real-world situations. Computational Thinking
Identify the inputs and outputs required in a solution. Computational Thinking
Identify pre-planning in a suggested problem and solution. Computational Thinking
Explain the need for pre-conditions when executing an algorithm. Computational Thinking
Outline the pre- and post-conditions to a specified problem. Computational Thinking
Identify exceptions that need to be considered in a specified problem solution. Computational Thinking
Identify the parts of a solution that could be implemented concurrently. Computational Thinking
Describe how concurrent processing can be used to solve a problem. Computational Thinking
Evaluate the decision to use concurrent processing in solving a problem. Computational Thinking
Identify examples of abstraction. Computational Thinking
Explain why abstraction is required in the derivation of computational solutions for a specified situation. Computational Thinking
Construct an abstraction from a specified situation. Computational Thinking
Distinguish between a real-world entity and its abstraction. Computational Thinking
Describe the characteristics of standard algorithms on linear arrays. Computational Thinking
Outline the standard operations of collections. Computational Thinking
Discuss an algorithm to solve a specific problem. Computational Thinking
Analyse an algorithm presented as a flow chart. Computational Thinking
Analyse an algorithm presented as pseudocode. Computational Thinking
Construct pseudocode to represent an algorithm. Computational Thinking
Suggest suitable algorithms to solve a specific problem. Computational Thinking
Deduce the efficiency of an algorithm in the context of its use. Computational Thinking
Determine the number of times a step in an algorithm will be performed for given input data. Computational Thinking
State the fundamental operations of a computer. Computational Thinking
Distinguish between fundamental and compound operations of a computer. Computational Thinking
Explain the essential features of a computer language. Computational Thinking
Explain the need for higher level languages. Computational Thinking
Outline the need for a translation process from a higher level language to machine executable code. Computational Thinking
Define the terms: variable, constant, operator, object. Computational Thinking
Define common operators. Computational Thinking
Analyse the use of variables, constants and operators in algorithms. Computational Thinking
Construct algorithms using loops, branching. Computational Thinking
Describe the characteristics and applications of a collection. Computational Thinking
Construct algorithms using the access methods of a collection. Computational Thinking
Discuss the need for sub-programmes and collections within programmed solutions. Computational Thinking
Construct algorithms using pre- defined sub-programmes, one- dimensional arrays and/or collections. Computational Thinking

References[edit]