Colorimeter calibration system and methods

What is claimed is: 1. A colorimeter comprising: a microprocessor with multiple switchable output ports; a light source connected to three of the output ports; a photo transistor for sensing reflected light; at least two different resistors, each of the resistors connected to a corresponding additional one of the output ports, the at least two different resistors configured to connect the photo transistor to the microprocessor, the microprocessor configured to cycle through the at least two resistors and select a calibration based on a first predefined voltage target for reflection from a first reference surface and a second predefined voltage target for reflection from a second reference surface. 2. The colorimeter of claim 1 , wherein selecting a calibration further comprises the microprocessor configured to select a resistor or a set of resistors based on the first predefined voltage target for reflection from the first reference surface and the second predefined voltage target for reflection from the second reference surface; wherein the first predefined voltage target is different than the second predefined voltage target. 3. The colorimeter of claim 2 , wherein selecting a calibration comprises the microprocessor configured to store a resistor or resistor combination that allows the photo transistor to generate a lowest voltage for reflection from the first reference surface; wherein selecting a calibration comprises the microprocessor configured to store a resistor or resistor combination that allows the photo transistor to generate a highest voltage for reflection from the second reference surface; wherein the first reference surface is colored black and the second reference surface is colored white. 4. The colorimeter of claim 2 , further comprises the microprocessor is configured to determine which of the at least two different resistors generate the largest difference between a reflectance value from a reflection of the first reference surface and a reflectance value from a reflection of the second reference surface by cycling through the at least two resistors for the light source; and wherein the first predefined voltage target is lower than the second predefined voltage target. 5. The colorimeter of claim 1 , wherein light source is a tri-band wavelength light source that further comprises one or more lights that are configured to generate colored lights comprising at least one of a red, green or blue light when activated. 6. The colorimeter of claim 5 , wherein the microprocessor colorimeter is configured to determine which of the at least two different resistors or a combination of the two resistors generate the difference gradient between a reflectance value from a reflection of the first reference surface and a reflectance value from a reflection of the second reference surface by cycling through the at least two resistors for the red light; wherein the microprocessor is further configured to determine which of the at least two different resistors or the combination of the two resistors generate the largest difference between a reflectance value from a reflection of the first reference surface and a reflectance value from a reflection of the second reference surface by cycling through the at least two resistors for the green light; wherein the microprocessor is further configured to determine which of the at least two different resistors or the combination of the two resistors generate the largest difference between a reflectance value from a reflection of the first reference surface and a reflectance value from a reflection of the second reference surface by cycling through the at least two resistors for the blue light. 7. The colorimeter of claim 6 , wherein the microcontroller is configured to use the determined resistance load for the red light; wherein the microcontroller is configured to use the determined resistance load for the green light; wherein the microcontroller is configured to use the determined resistance load for the blue light; wherein the resistance load is one resistor or a combination of resistors. 8. The colorimeter of claim 1 , wherein the two different resistors are connected in parallel to the photo transistor. 9. The colorimeter of claim 1 , wherein the light source comprises a red light source, a green light source and a blue light source that are powered sequentially to generate a light that shines and reflects from the first reference surface or the second reference surface; wherein the microcontroller is configured to determine whether either of the at least two resistors or the combination of the at least two resistors generates the largest difference between a reflectance value from a reflection of the first reference surface and a reflectance value from a reflection of the second reference surface. 10. The colorimeter of claim 1 , wherein the microprocessor is configured to choose a first resistor combination for a first light emitter and a second resistor combination for a second light emitter, the first resistor combination providing a different resistance than the second resistor combination. 11. A system comprising: a microcontroller having an input port and a plurality of switchable ports including a first port, a second port, a third port, and a fourth port; a light source having a first light emitter connected to the first port and a second light emitter connected to the second port; and a plurality of resistors including a first resistor connected to the third port and a second resistor connected to the fourth port, the first and second resistors being connected in parallel to the photo transistor, each resistor having a different resistance; wherein the microcontroller is configured to select a calibration by cycling through resistance combinations of the plurality of resistors, and to identify a combination of the plurality of resistors which produces a first voltage at the input port that best approximates a first predefined voltage target when the selected surface is a first reference surface and produces a second voltage at the input port that approximates a second predefined voltage target when the selected surface is a second reference surface. 12. The system of claim 11 , wherein the input port is connected in parallel to the phototransistor with the plurality of resistors; and wherein the first reference surface is colored black and the second reference surface is colored white. 13. The system of claim 11 , wherein the microcontroller chooses a first resistor combination for the first light emitter and a second resistor combination for the second light emitter, the first resistor combination providing a different resistance than the second resistor combination. 14. The system of claim 11 , wherein the microcontroller configured to store the first resistor combination for future use with the first light emitter, and the second resistor combination for future use with the second light emitter. 15. The system of claim 11 , wherein the system is included in a playset, the playset including an environment for a plurality of toys, each toy having a colored surface identifiable by the system, the system having a speaker configured to communicate a predetermined message to a user upon identification of the colored surface of one of the toys of the plurality of toys. 16. The system of claim 11 , wherein the photo transistor is configured to sense light reflected off of a surface from the light source, the first and second light emitters being connected in parallel to the photo transistor. 17. A metho