Spectroscopic Finger Ring for Compositional Analysis of Food or Other Environmental Objects

I claim: 1 . A wearable device for food identification and quantification comprising: a camera which takes pictures of nearby food, wherein these food pictures are analyzed in order to identify the types and quantities of food; a light-emitting member which projects a light-based fiducial marker on, or in proximity to, the nearby food as an aid in estimating food size; a spectroscopic optical sensor, wherein this spectroscopic optical sensor collects data concerning light that is reflected from, or has passed through, the nearby food and wherein this data is analyzed to identify the types of food, the types of ingredients in the food, and/or the types of nutrients in the food; an attachment mechanism, wherein this attachment mechanism is configured to hold the camera, the light-emitting member, and the spectroscopic optical sensor in close proximity to the surface of a person's body; and an image-analyzing member which analyzes the food pictures. 2 . The device in claim 1 wherein the attachment mechanism is configured to be worn on or around the person's finger. 3 . The device in claim 1 wherein the attachment mechanism is configured to be worn on or around the person's wrist and/or forearm. 4 . The device in claim 1 wherein the attachment mechanism is configured to be worn on, in, or around the person's ear. 5 . The device in claim 1 wherein the attachment mechanism is configured to be worn on or over the person's eyes. 6 . The device in claim 1 wherein the attachment mechanism is configured to be worn on or around the person's neck. 7 . A wearable spectroscopic device for compositional analysis of environmental objects comprising: a finger ring, wherein this finger ring further comprises: a finger-encircling portion, wherein this finger-encircling portion is configured to encircle at least 70% of the circumference of a person's finger, wherein this finger-encircling portion has an interior surface which is configured to face toward the surface of the person's finger when worn, wherein this finger-encircling portion has a central proximal-to-distal axis which is defined as the straight line which most closely fits a proximal-to-distal series of centroids of cross-sections of the interior surface, and wherein proximal is defined as being closer to a person's elbow and distal is defined as being further from a person's elbow when the person's arm, hand, and fingers are fully extended; a light-emitting member which projects a beam of light along a proximal-to-distal vector toward an object in the person's environment, wherein this vector, or a virtual extension of this vector, is either parallel to the central proximal-to-distal axis or intersects a line which is parallel to the central proximal-to-distal axis forming a distally-opening angle whose absolute value is less than 45 degrees; and a spectroscopic optical sensor which collects data concerning the spectrum of light which is reflected from, or has passed through, the object in the person's environment, wherein data from the spectroscopic optical sensor is used to analyze the composition of this object, and wherein this spectroscopic optic sensor is selected from the group consisting of: spectroscopy sensor, spectrometry sensor, white light spectroscopy sensor, infrared spectroscopy sensor, near-infrared spectroscopy sensor, ultraviolet spectroscopy sensor, ion mobility spectroscopic sensor, mass spectrometry sensor, backscattering spectrometry sensor, and spectrophotometer. 8 . The device in claim 7 wherein the beam of light projected by the light-emitting member is near-infrared light, infrared light, or ultra-violet light. 9 . The device in claim 7 wherein the beam of light projected by the light-emitting member is white light and/or reflected ambient light. 10 . The device in claim 7 wherein the beam of light projected by the light-emitting member is coherent light. 11 . The device in claim 7 wherein this device further comprises a laser pointer which is moved by the person in order to direct a visible beam of coherent light toward an object in the environment in order to guide, direct, select, adjust, and/or trigger spectroscopic analysis of this object. 12 . The device in claim 7 wherein the vector of the beam of light projected by the light-emitting member is automatically changed in response to detection of an object in the environment and/or changes in the location of an object in the environment. 13 . The device in claim 7 wherein the vector of the beam of light projected by the light-emitting member is selected in order to direct reflected light back to the spectroscopic optical sensor from an object at a selected focal distance, wherein this selected focal distance is selected based on detection of the object at the selected distance, and wherein measurement of the object's distance is based on image analysis, reflection of light energy, reflection of radio waves, reflection of sonic energy, and/or gesture recognition. 14 . The device in claim 7 wherein the vector of the beam of light emitted by the light-emitting member is varied in order to scan for objects in the environment at different distances and/or to scan a larger portion of the surface of an object in the environment. 15 . The device in claim 7 wherein this device further comprises a data processing unit which at least partially processes data from the spectroscopic optical sensor. 16 . The device in claim 7 wherein this device further comprises a wireless data transmitter through which the device is in wireless communication with another wearable device and/or a remote computer and wherein information concerning the composition of the environmental object is displayed by the other wearable device and/or remote computer. 17 . The device in claim 7 wherein this device further comprises a motion sensor and wherein motion patterns are analyzed in order to trigger or adjust the parameters of a spectroscopic scan of an object in the environment. 18 . The device in claim 17 wherein a spectroscopic scan is triggered when motion patterns indicate that a person is eating. 19 . The device in claim 18 wherein the device performs multiple spectroscopic scans, at different times, while a person is eating in order to better analyze the overall composition of food with different internal layers and/or a non-uniform ingredient structure. 20 . A wearable spectroscopic device for compositional analysis of environmental objects comprising: a finger ring, wherein this finger ring further comprises: a finger-encircling portion, wherein this finger-encircling portion is configured to encircle at least 70% of the circumference of a person's finger when worn, wherein a virtual cylinder is defined as the cylinder which most closely approximates the shape of the finger-encircling portion, wherein this finger-encircling portion has a central proximal-to-distal axis which is defined as the central longitudinal axis of the virtual cylinder; a light-emitting member, wherein this light-emitting member projects a beam of light toward an object in the person's environment, and wherein this vector, or a virtual-extension of this vector, is either parallel to the central proximal-to-distal axis or intersects a line which is parallel to the central proximal-to-distal axis forming a distally-opening angle whose absolute value is less than 45 degrees; and a spectroscopic optical sensor, wherein this spectroscopic optical sensor which collects data concerning the spectrum o