Thermochromic actuators

What is claimed is: 1. A thermochromic actuator, comprising: a thermal responsive artificial actuator; and a thermochromic coating comprising a thermochromic material, wherein: the thermochromic coating is disposed on an entire surface of the thermal responsive artificial actuator and is infiltrated into the thermal responsive artificial actuator; the thermochromic coating has a transition temperature below a rated critical temperature of the thermal responsive artificial actuator; and the thermochromic coating produces a first color below the transition temperature and a second color above the transition temperature, the second color being different from the first color and indicative of a change of the thermal responsive artificial actuator operation. 2. The thermochromic actuator of claim 1 , wherein: the thermally activated artificial actuator is a polymer based artificial actuator; the polymer based artificial actuator comprises: a core fiber that has a radial thermal expansion coefficient, and a conductive element fixed to the core fiber; and the thermochromic coating is disposed on a surface of the core fiber or the conductive element. 3. The thermochromic actuator of claim 2 , wherein the thermochromic coating has a transition temperature below a rated critical temperature of the core fiber and the conductive element. 4. The thermochromic actuator of claim 3 , wherein: the thermochromic coating comprises a plurality of thermochromic materials with a plurality of transition temperatures and a plurality of colors; and the plurality of transition temperatures causes a plurality of color transitions before reaching the rated critical temperature. 5. The thermochromic actuator of claim 2 , wherein the thermochromic coating comprises an irreversible thermochromic material. 6. The thermochromic actuator of claim 2 , wherein the thermochromic material has a transition temperature correlated to a level of actuation in the polymer actuator. 7. The thermochromic actuator of claim 6 , wherein: the thermochromic coating comprises a plurality of thermochromic materials with a plurality of transition temperatures; and the plurality of transition temperatures is correlated to a plurality of levels of actuation in the polymer actuator. 8. The thermochromic actuator of claim 2 , wherein: the thermochromic coating comprises a thermochromic material with a transition from a substantially black color to a substantially white color; the substantially black color absorbs thermal radiation to aid in heating the polymer actuator; and the substantially white color radiates thermal radiation to aid in cooling the polymer actuator. 9. The thermochromic actuator of claim 8 , wherein: the thermochromic coating comprises a plurality of thermochromic materials with a plurality of transition temperatures; a lower limit and an upper limit of an operational temperature range of the polymer actuator are indicated by the substantially black and substantially white colors; and the transition temperatures between the lower and upper limits of the operational temperature range are indicated by colors other than the substantially black or substantially white colors. 10. A method of manufacturing the thermochromic actuator of claim 2 , comprising: selecting a thermochromic material based upon a group of parameters comprising: a transition temperature, and a color; mixing the thermochromic material into a substantially homogeneous mixture; applying the substantially homogeneous mixture onto a surface of the polymer actuator; and drying the substantially homogeneous mixture to form a thermochromic coating. 11. The thermochromic actuator of claim 1 , wherein: the thermal responsive artificial actuator is a carbon nanotube yarn actuator; and the thermochromic coating is disposed on an entire surface of the carbon nanotube yarn actuator and is infiltrated into the carbon nanotube yarn actuator. 12. The thermochromic actuator of claim 11 , wherein: the thermochromic coating comprises a plurality of thermochromic materials with a plurality of transition temperatures; a lower limit and an upper limit of an operational temperature range of the carbon nanotube yarn actuator are indicated by the substantially black and substantially white colors; and the transition temperatures between the lower and upper limits of the operational temperature range are indicated by colors other than the substantially black or substantially white colors. 13. The thermochromic actuator of claim 1 , wherein the thermochromic coating is a blend further comprising: a guest actuation material. 14. The thermochromic actuator of claim 13 , wherein a ratio of the thermochromic material to the guest actuation material is between 1:5 and 1:20. 15. The thermochromic actuator of claim 13 , wherein the guest actuation material is a silicone rubber. 16. The thermochromic actuator of claim 1 , wherein: the thermochromic coating comprises a plurality of thermochromic materials with a plurality of transition temperatures and a plurality of colors; the plurality of transition temperatures a plurality of color transitions; and one of the plurality of transition temperatures is below one of the rated critical temperature. 17. The thermochromic actuator of claim 1 , wherein the thermochromic coating comprises an irreversible thermochromic material. 18. The thermochromic actuator of claim 1 , wherein: the thermochromic coating comprises a thermochromic material with a transition from a substantially black color to a substantially white color; the substantially black color absorbs thermal radiation to aid in heating the thermal responsive artificial yarn actuator; and the substantially white color radiates thermal radiation to aid in cooling the thermal responsive artificial yarn actuator. 19. A method of manufacturing the thermochromic actuator of claim 1 , the method comprising: selecting a thermochromic material based upon a group of parameters comprising: a transition temperature; and transition colors, the transition colors corresponding to the transition temperature; mixing the thermochromic material and a guest actuation material into a substantially homogeneous mixture; applying the substantially homogeneous mixture to a nanotube yarn surface and infiltrate the substantially homogeneous mixture into the nanotube yarn before twisting; drying the substantially homogeneous mixture to form an infiltrated yarn; twisting the infiltrated nanotube yarn into a nanotube yarn actuator; applying an additional amount of the substantially homogeneous mixture to a surface of the thermal responsive yarn actuator; and drying the thermal responsive yarn actuator with the additional amount of the substantially homogeneous mixture, wherein: the transition temperature is indicative of a change of thermal responsive yarn actuator operation selected from a yarn actuator degradation and one of actuation levels of the thermal responsive yarn actuator. 20. The method of claim 19 , wherein the selected thermochromic material and guest actuation material are mixed with a ratio ranging from 1:5 to 1:20. 21. The thermochromic actuator of claim 1 , wherein the change of the thermal responsive artificial actuator operation is a beginning of the thermal responsive artificial actuator degradation. 22. The thermochromic actuator of claim 1 , wherein the change of the thermal responsive artificial actuat