In order to support the adaptive SGfL, teaching materials must be represented in game component that becomes the target of adaptivity. If adaptive architecture of the game only use game state (GS) to recognize player's state, SGfL require another indicator -learning state (LS)- to identify the learning progress. It is a necessary to formulate computational framework for both states in SGfL.The computational framework was divided into two moduls, macro-strategy and micro-strategy. Macro-strategy control the learning path based on learning map in AND-OR Graph data stucture. This paper focus on the Macro-strategy modul, that using online, direct, and centralized adaptivity method. The adaptivity in game has five components as its target. Based on those targets, eight development models of SGfL concept was enumerated. With similarity and difference analysis toward possibility of united LS and GS in computational framework to implement the nine SGfL concept into design and application, there are three groups of the development models i.e. (1) better united GS and LS, (2) must manage LS and GS as different entity, and (3) can choose whether to be united or not. In the model which is united LS with GS, computing model at the macro-strategy modul use and-or graph and forward chaining. However, in the opposite case, macro-strategy requires two intelligent computing solutions, those are and-or graph with forward chaining to manage LS collaborated with Finite State Automata to manage GS. The proposed computational framework of SGfL was resulted from the similarity and difference analysis toward all possible representations of teaching materials into the adaptive components of the game. It was not dependent of type of learning domain and also of the game genre.

Serious Game; Adaptivity; Forward Chaining; FSA; Instructional Design

Lopez Ricardo , Bidarra Rafael. Adaptivity Challenges in Games and Simulation : A Survey. IEEE Transaction on Computational Intelligence and AI in Games. 2011; 3(2).

Reigeluth, C. Instructional Design: Theory and Model Second Edition. Lawrence Erlbaum Associates, 1983

Kickmeier-Rust MD, Albert. Micro-adaptivity:protectingimmersionin didacticallyadaptivedigitaleducationalgames, Journal of Computer Assisted Learning .2010; 26, pp 95–105

Jatain Aman. Comparison of Domain Analysis Methods and their supporting Quality Attributes. Thesis. Patiala , Thapar University ;2009.

Hirave Kanifnath S, Hanchate Dinesh Bhagwan. Survey on ExFeature: A Feature Modelling and Recommending Technique For Domain Oriented Product Listing. International Journal of Engineering Research and General Science. 2014; 2(6).

Westra Josst, et All. Guiding User Adaptation in Serious Games. Agent for Games and Simulation II, LNAI 6525. 2011; pp. 117-131, @ Springer-Verlag Berlin Heidelberg

Westra Joss et All. Keep the trainee on track. IEEE conference Computing Intelligent Game, 2010, Denmark

Lee Seong Jae, Liu Yun End, Popovic Zoran, Learning Individual Behaviour in Educational Game: a Data Driven Approach. The 7th International Conference on Educational Data Mining (EDM ). 2014

Koidl Kevin , Mehm Kevin et All, Dynamically adjusting Digital Educational Games Toward Learning Objectives, The 3rd European Conference on Game Based Learning, 2010; 177-184,

B.Magerko, C.Heeter, et All, Intelligent Adaptation of Digital gamae-based Learning, ACM Conference Future Play, Canada, 2008

Minovic Miroslav, et All. Visualisation of Student Learning Model in Serious Games. Computers in Human behaviour. 2014

Richard Rouse. Game Design: Theory & Practice Second Edition. Wordware Publishing, Inc, 2005

Rollings A, Morris D . Game Architecture and Desisgn: A New Edition. Indianapolis, New Riders Publishing, , 2004

Fabricatore Carlo, Gameplay and Game Mechanics Design : A Key to Quality in Videogames. OECD-CERI Expert Meeting on Videogames and Education.2007

Russel Stuart , Norvig, Peter . Artificial Intelligence a Modern Approach. Prentice Hall, 2003