Self-illuminated handheld lens for retinal examination and photography and related method thereof

What is claimed is: 1. A self-illuminated handheld lens for wide angle retinal viewing of a subject eye, comprising: an aspherical objective lens having a symmetric viewing axis and defining a viewing channel; a contact lens positioned in front of said aspherical objective lens to be applied to said subject eye; plurality of LEDs positioned around said viewing axis and configured to illuminate said subject eye outside from said viewing channel; a light baffle configured to block stray light of said LEDs from getting into said viewing channel; and cross polarization means incorporated between said plurality of LEDs and said viewing channel of said aspherical objective lens, wherein said cross polarization means comprises a first polarizer attached to cover said LEDs and a second polarizer positioned in said viewing channel of said aspherical objective lens. 2. The self-illuminated handheld lens of claim 1 , further comprising: an electronic controller powering said plurality of LEDs and controlling each LED independently. 3. The self-illuminated handheld lens of claim 1 , wherein said aspherical objective lens has a field of view of 120 degrees or wider on said retina. 4. The self-illuminated handheld lens of claim 1 , wherein said contact lens has a diameter approximate 10 mm. 5. The self-illuminated handheld lens of claim 1 , wherein said LEDs are each a high brightness, surface mounted, white light LED. 6. The self-illuminated handheld lens of claim 1 , wherein said light baffle is made of black outside said viewing channel. 7. A wide field fundus camera for taking wide field of view retina image of a subject eye, comprising: a self-illuminated handheld lens incorporated plurality of LEDs and positioned to form a retinal image with a wide field of view, wherein said wide field of view is defined as greater than 75 degrees; a digital camera disposed to capture said retinal image; and an electronic controller configured to power said plurality of LEDs. 8. The wide field fundus camera of claim 7 , further comprising: a software algorithm incorporated with said electronic controller and said digital camera to produce plurality of retinal images with sectional illumination on each of said plurality of images. 9. The wide field fundus camera of claim 7 , further comprising: a software algorithm implemented to process said retinal image to reduce image haze dynamically. 10. The wide field fundus camera of claim 8 , further comprising: a software algorithm implemented to process said plurality of retinal images and to stitch them into a wide field single image.