Self-retracting tape rule

What is claimed is: 1. A self-retracting tape rule, the tape rule comprising: an elongated tape rule blade configured for measurement, the elongated tape rule blade having measurement indicia thereon, the elongated tape rule blade comprising a substrate, wherein the measurement indicia comprise portions of the substrate with local nanostructured changes relative to other portions of the substrate, wherein the local nanostructured changes are configured to trap or absorb light to create color contrasts with the other portions of the substrate, and wherein the local nanostructured changes comprise an annealed metallic structure or an oxidized metallic structure; a reel configured to retract the elongated tape rule blade from an extended position to a wound position; a spring configured to apply a rotational bias to the reel that rotates the reel to retract the elongated tape rule blade into the wound position; a lock configured to selectively engage the elongated tape rule blade to maintain the elongated tape rule blade in the extended position; and a housing configured to house the elongate tape rule blade, the reel, the spring, and the lock. 2. The tape rule of claim 1 , wherein the substrate is formed from metal. 3. The tape rule of claim 1 , wherein the elongated tape rule blade comprises a coating, and wherein the coating comprises an anodized portion of the substrate of the elongated tape rule blade. 4. The tape rule of claim 1 , wherein the elongated tape rule blade comprises a coating, and wherein the coating comprises a ceramic physical vapor deposition (PVD) coating on the elongated tape rule blade. 5. The tape rule of claim 1 , wherein the measurement indicia are formed in the substrate by impinging the substrate with pulsed radiation having an ultraviolet, visible, or infrared wavelength, a pulse width of less than 20 picoseconds, a power of less than 100 Watts, and a repetition rate up to 100 gigahertz. 6. The tape rule of claim 1 , wherein the measurement indicia are formed in the substrate by impinging the substrate with radiation from a picosecond laser. 7. A method of forming a self-retracting tape rule, the method comprising: providing a substrate for an elongated tape rule blade; forming measurement indicia on the substrate of the elongated tape rule blade such that the elongated tape rule blade is configured for measurement, wherein the measurement indicia comprise portions of the substrate with local nanostructured changes relative to other portions of the substrate, wherein the local nanostructured changes are configured to trap or absorb light to create color contrasts with the other portions of the substrate, and wherein the local nanostructured changes comprise an annealed metallic structure or an oxidized metallic structure; coupling a reel to the elongated tape rule blade, the reel configured to retract the elongated tape rule blade from an extended position to a wound position; coupling a spring to the reel, the spring configured to apply a rotational bias to the reel that rotates the reel to retract the elongated tape rule blade into the wound position; and assembling the elongated tape rule blade, the reel, and the spring in a housing. 8. The method of claim 7 , further comprising forming the measurement indicia in the substrate by impinging the substrate with radiation from a picosecond laser. 9. The method of claim 8 , wherein the radiation from the picosecond laser has a pulse width of less than 20 picoseconds. 10. The method of claim 8 , wherein the radiation from the picosecond laser has a power of less than 100 Watts. 11. The method of claim 8 , wherein the radiation from the picosecond laser produces black colored measurement indicia in the substrate. 12. The method of claim 7 , wherein the measurement indicia are formed on the substrate by impinging the substrate with pulsed radiation having an ultraviolet, visible, or infrared wavelength, a pulse width of less than 20 picoseconds, a power of less than 100 Watts, and a repetition rate up to 100 gigahertz. 13. The method of claim 12 , wherein the pulsed radiation has an ultraviolet wavelength. 14. The method of claim 12 , wherein the pulsed radiation has a pulse with of less than 10 picoseconds. 15. The method of claim 12 , wherein the pulsed radiation has a power of less than 5 Watts. 16. The method of claim 12 , wherein the repetition rate is up to 50 gigahertz. 17. The method of claim 7 , wherein the measurement indicia are formed in the substrate with radiation from a picosecond laser substantially without photothermal effects on the substrate. 18. The method of claim 7 , further comprising coating the substrate of the elongated tape rule blade with a non-polymer coating, the non-polymer coating configured to provide one or more of color, environmental protection, and/or abrasion resistance to the elongated tape rule blade. 19. A method of forming a self-retracting tape rule, the method comprising: providing a substrate for an elongated tape rule blade; forming measurement indicia on the substrate of the elongated tape rule blade such that the elongated tape rule blade is configured for measurement, wherein the measurement indicia are formed on the substrate by impinging the substrate with pulsed radiation having an ultraviolet, visible, or infrared wavelength, a pulse width of less than 20 picoseconds, a power of less than 100 Watts, and a repetition rate up to 100 gigahertz; coupling a reel to the elongated tape rule blade, the reel configured to retract the elongated tape rule blade from an extended position to a wound position; coupling a spring to the reel, the spring configured to apply a rotational bias to the reel that rotates the reel to retract the elongated tape rule blade into the wound position; and assembling the elongated tape rule blade, the reel, and the spring in a housing. 20. A self-retracting tape rule, the tape rule comprising: an elongated tape rule blade configured for measurement, the elongated tape rule blade having measurement indicia thereon, the elongated tape rule blade comprising a substrate, wherein portions of the substrate comprise local nanostructured changes relative to other portions of the substrate, wherein the local nanostructured changes comprise an annealed metallic structure or an oxidized metallic structure; a reel configured to retract the elongated tape rule blade from an extended position to a wound position; a spring configured to apply a rotational bias to the reel that rotates the reel to retract the elongated tape rule blade into the wound position; a lock configured to selectively engage the elongated tape rule blade to maintain the elongated tape rule blade in the extended position; and a housing configured to house the elongate tape rule blade, the reel, the spring, and the lock.