The　coefficient　of　thermal　expansion　(CTE)　is　an　important　parameter　for　the　thermophysical　properties　of　materials.　Mostly,　in　aerospace　engineering,　satellites,　hypersonic　vehicles,　precision　instruments　and　microelectronic　packages,　numerous　thermal　deformation　structures　in　severe　environment　full　of　drastic　temperature　changes　are　required　to　be　controlled　precisely.　Therefore,　the　development　of　adjustable　thermal　expansion　materials　is　of　significance　in　engineering　applications.　Based　on　the　Miura-ori　structure,　this　paper　adopts　materials　with　respectively　diverse　CTEs　as　components　to　generate　thermal　stresses　mismatch　principle　and　proposes　a　design　method　for　origami　metamaterials　with　adjustable　in　situ　positive/negative/zero　expansion　functions.　Employing　the　methods　of　finite　element　calculation　and　deformation　analysis,　the　deformation　results　of　this　metamaterial　are　displayed　and　discussed.　Also,　an　origami　metamaterial　with　adjustable　positive/negative/zero　expansion　function　can　be　obtained　by　adjusting　the　material　distribution　of　the　structure.　Moreover,　the　mapping　relationship　between　the　folding　angle　and　the　geometric　parameter　of　the　structure　is　established.　In　the　light　of　this　design　method　of　tunable　CTE　metamaterials,　additionally,　the　metamaterial　can　achieve　precise　control　of　thermal　deformation　and　optimize　service　reliability　in　extreme　environments.