Smart soft composite actuator

The invention claimed is: 1. A smart soft composite actuator comprising: a first smart material and a separate second smart material whose shapes are changeable based on an external signal; and a matrix configured to support the first and second smart materials and determine an external shape of the smart soft composite actuator, wherein the first and second smart materials are inside the matrix or in a surface of the matrix, the first smart material is completely on one side of a central plane of the matrix, and the second smart material is completely on an opposite side of the central plane of the matrix, spaced apart from the first smart material, and at least one of in-plane shear deformation and out-of-plane deformation is realized by controlling positions of the first and second smart materials. 2. The actuator of claim 1 , wherein the first and second smart materials are in a horizontal central plane of the matrix, but completely outside of a vertical central plane of the matrix to realize the in-plane shear deformation. 3. The actuator of claim 1 , wherein the first and second smart materials are completely outside of a horizontal central plane of the matrix, but in a vertical central plane of the matrix to realize the out-of-plane deformation. 4. The method of claim 1 , wherein the first and second smart materials are completely outside of a horizontal central plane of the matrix and completely outside of a vertical central plane of the matrix to realize the in-plane shear deformation and out-of-plane deformation. 5. A smart soft composite actuator comprising: a first smart material and a separate second smart material whose shapes are changeable based on an external signal; and a directional material configured to support the first and second smart materials, determine an external shape of the smart soft composite actuator, and restrict deformation of the smart soft composite actuator in a specific direction, wherein the first and second smart materials are inside the directional material or in a surface of the directional material, the first smart material is completely on one side of a central plane of the directional material, and the second smart material is completely on an opposite side of the central plane of the directional material, spaced apart from the first smart material, and at least one of in-plane shear deformation, out-of-plane deformation, and twisting is realized by controlling a position of the first and second smart materials and a directionality of directional material. 6. The actuator of claim 5 , wherein the first and second smart materials are completely outside of a horizontal central plane of the directional material, but in a vertical central plane of the directional material, and the directional material has orthotropic properties adapted to realize the out-of-plane deformation. 7. The actuator of claim 5 , wherein the first and second smart materials are completely outside of a horizontal central plane of the directional material, but in a vertical central plane of the directional material, and wherein the directional material has anisotropic properties adapted to realize the out-of-plane deformation and twisting. 8. The actuator of claim 5 , wherein the first and second smart materials are completely outside of a horizontal central plane of the directional material and completely outside of a vertical central plane of the directional material, and wherein the directional material has orthotropic properties adapted to realize the in-plane shear deformation and out-of-plane deformation. 9. A smart soft composite actuator comprising: a first smart material and a second smart material whose shapes are changeable based on an external signal; a directional material configured to restrict deformation in a specific direction; and a matrix configured to (i) support the smart material and the directional material and (ii) determine an external shape of the smart soft composite actuator, wherein the first and second smart materials are inside the matrix or in a surface of the matrix, the first smart material is completely on one side of a central plane of the matrix, and the second smart material is completely on an opposite side of the central plane of the matrix, spaced apart from the first smart material, the directional material is inside the matrix, and at least one of in-plane shear deformation, out-of-plane deformation, and twisting is realized by controlling a position of the smart material, a position of the directional material, and a directionality of the directional material. 10. The actuator of claim 9 , wherein the first and second smart materials are in a horizontal central plane of the matrix, but completely outside of a vertical central plane of the matrix, and the directional material has orthotropic properties adapted to realize the in-plane shear deformation. 11. The actuator of claim 9 , wherein the first and second smart materials are completely outside of a horizontal central plane of the matrix, but in a vertical central plane of the matrix, and the directional material has orthotropic properties adapted to realize the out-of-plane deformation, and the directional material is in the horizontal central plane of the matrix. 12. The actuator of claim 9 , wherein the first and second smart materials are completely outside of a horizontal central plane of the matrix and completely outside of a vertical central plane of the matrix, and the directional material has orthotropic properties adapted to realize the in-plane shear deformation and out-of-plane deformation, and the directional material is in the horizontal central plane of the matrix. 13. The actuator of claim 9 , wherein the first and second smart materials are completely outside of a horizontal central plane of the matrix but in a vertical central plane of the matrix, and the directional material has anisotropic properties adapted to realize the out-of-plane deformation and twisting, and the directional material is in the horizontal central plane of the matrix. 14. The actuator of claim 9 , wherein the first and second smart materials are completely outside of a horizontal central plane of the matrix and completely outside of a vertical central plane of the matrix, and the directional material has anisotropic properties adapted to realize the in-plane shear deformation, out-of-plane deformation and twisting, and the directional material is in the horizontal central plane of the matrix. 15. The actuator of claim 9 , wherein the matrix comprises a material whose Young's modulus is not more than 1 GPa. 16. The actuator of claim 9 , wherein the directional material comprises a material whose Young's modulus is not less than 1 GPa. 17. The actuator of claim 9 , wherein the matrix comprises an elastomeric polymer, silicon, or polydimethylsiloxane (PDMS), and has a Young's modulus of not more than 1 GPa. 18. The actuator of claim 5 , wherein the directional material comprises a material having a Young's modulus of not less than 1 GPa. 19. The actuator of claim 18 , wherein the matrix comprises an elastomeric polymer, silicon, or polydimethylsiloxane (PDMS). 20. The actuator of claim 5 , wherein the directional material comprises a mesh structure having openings therein, the directional material has a stiffness in a specific direction that is greater than its stiffness in other directions, and the openings in the mesh structure include the matrix.