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MODULE 2 UNIT-1! Digital image fundmentals „ Digitat Image Pret deacke be ii âto pmcning Qo two olistontopat cture by a cligital Cornputer, * A monousrome 1% ⏠8&8 an image bh a two dimensional intensity function 40uy), hoheve % ancy denote Spatial co-ordinatin and tke Value 3 t0Ly) & Psopertional to tha brightnians (or grey level) i] an Image ak (x,y) Point. ortg ing y 44) a * A digital image wan image 410y) thot has been discretized beth [n Spetiok Co-ordinates anck beightness, : * A Hagital Image Can be Considlered aL a motsic Whose sO, and Columns Inclice, yelex to a point in che image and Corres pondin a matrix, element value rent identifies the Grsouy level at that Point, * Metrix Clements digital image matsin ave "| Colled as image elements, picture elements, plats os pels, Types 4 Emaae, browsing * Low devel Prouxing Include, notse veduction, Contrast enhancement and fmage Shaspening. Input and output 3 tow level Pamaming ase nae + Mid Level processing Incucles segmentation Prous, bshich os | Prroters, posstitioning an image Into regions. os subdiVvittons. Here inpubi axe mage but outpub ave attributis Extratiid from image like edaes, Contours cuncl identijying 4 individual Object, | oe High level Proussing Involves fmaqe an th, ( uNnderktatin 9 4% Collection 4 ecogniaed objeck) ea '- In atttomoted Uassitication feuik and vegetables Images gq ou Kind g fruit and vege- -tobles owe abyutred, Preprovened â(tow ever), Seam, - ented and described (mid Level) in a form Suitable fox Cornputers Paeeiieas and finally frutt and Vegetoblers are x nized Che veq *cog ! C âgh level), > a ° *~ Fundamental Ateps in Rigitas Lmage Paptessing Problem Domain: Image or data should be taken etsoretiy to the weyutserment, ox applications, applicable to other type 4 beige bai biomedical. images * Inge sertoration:- Thin 4b oa prows reconstsuctior] ot weenie an image tot hod been rade by using Some prior knowledge y De degradation Phenomenon, âŹ4!- Removal f Tr alla * color image Protessing:- This oma impostanie due to use canin Stantticant Increase fn" te digital images over tk, Intesnet, Jhis can be divided +o two major areag â> pull Color proussing }- proursing Ha Image e id Coles acnyired with a fut-Colov senor like*TV Comer, <> Pseudo - Color prousing!- Assignin porticulay monocrsome Intensity intensities, 9 a color toa mn Waage F * Wavelets and muttrrerolutfon Processing '- Waveli ase tte foundation tor Bepserenting mages tn Vortows degrees 3 Beolution . They ave also wii used for image Compression and nolre elimination, * Corapre sion t- This Atep Involves vecluthn the Htowage Spo veoyuired and abo tke bond woiolth peoyuired tov teansmitting, He fraoae stowage technology how [mproved Aignifican and BW Copobi ity has abo improved a tot due to te use optical fllowe but Si image Compresion is an important 3tep and dhe Atondawd Ctik- -narne..3pq) widely use. (aPeq + Jofnt Photographic Expest Group] y> | bs 4 Morphologicat prowsing.- This Step involve extra- ee Oe -cting [mage Components uweful in the veprerentation and description g tke Shape, x Seqmentation ' partitioning or subdividing tia, Image Into {ts Constituent powts os objects bs Calli as, Segmentation. A good Reqmentation protecuve helps In Sucumful fdentification 9 objects in an image and a weak Seqrnentation proteduse may lead to foiluse. Thevefove Segmentation pron should be very accurate . ~ Representation and chscsiption :- The output Segmentotion pxrows by wal data. Thit data howd be propesly wepresen tet In order to help further Prouusing. There ase two types 9 sepsesentation â> Boundasy representation :- Helps In studying external hope g on object, 1 => Regionot seporentation:- Helps In studying Intesnol pwoperties Uke texture, > In some applicationsâ both types 9 Cepsetentation B ued, Deseviption os feature Selection deals itt, extracting attsibulis foorn wepserentation bshich leads to getting Some dwuahttitotive information| intewat or helps in ea penti ating one chase 4 objeck from other. âScanned with CamScanner i physical dovie that w& Senitive to a band g @ Letrornag neti C Visible, Infrawd etc, and poduud an electrical eng: y Spectrum, ike X Rays , Signal proportional to enusgy level Sersoat > A Roleiser tor ecinven ing tte device output to digi tal, form. Network e Compulir "plows ime i i Mass Stomae Hardcopy figuee.2 f image . Preedthode Troge Sensors, peoblun domain + Specialized Image Paowising This Consirts Performs some Operations - tic logic unit and logical Operations on , Auth Opesation Os trey ave, digitised nose, Thils haxdware i. Aome-tim v hawd wave *- Dawe Wave digitizes Gnd a hardware that (ALU) bshich peyjorns Lusithemotic Carte may be axsithina- tke entive image, one is Averaging g whe image G2 Loon, end Subsystem . Important CharackeyiZtic. ters device ih ft, speed Q Opewotion. in ovdes to reduce tte 4 Catted ag front â% Computer :- Genevol Purpose Compubes is sed 2 image Prowsing System, It ton be Fangedk teom Pessonal Conmputes (pc) to Alpers Computes, Sometimes Specially dusignect Computess ave alo used [n oxen to gee seyulred level g pesformanc, + pelheont Trage Processing uses Speclalixed son trove foe Pexjprming Specific totks, Some wetl dufgned. Aoptwoawes cLLows the Uses to write Cocker, ÂŁq:-Matleb,c, Astra. Image » PC boved âi Image Prowsing CREAMâ usec for biologicot image. GRASS > Gjeogsaphic Resource Anatipis Support Sytem, OCTAVE > Open Source â> unitx Plat {osm treo image > open Sourte for pwject cevelopess, * Mags starags Mass, storage, Capability wb te most lo portant Pors t g image Procenting a@pplins An image g Sie 1024x1084 pinals venubrea one megabyte g storage Space D} @& number | images ave used then elidelâ ie becomes A problem. These awe three types 3 sabionamge, usec fn digi tol Image. Prowssing applications, i) Short tesm patasttng - used dieting Processing ii) on- Une Ftoraqe, - fos fast (foeayisen tly Used) ti Axchtval 4 @- fos storing image tohich i> d ase not dredhanl Used , Tage formation In the Eye i- In an osdina photo aphic Camera , Ae nan has a fixed focal length, anct focusing ot Vartous distanns & achieved by veaying the Aitance between the Lenk and the imaging Plane, ishtite: is. Pilm & tocatec. In tee human eye, tke Converse ik tours te aistance between He Lee and use imaging tegion (she, retina) & fixed, ancl 6% focal Len reeked to achieve proper focus i obtained by Varying ta Ahape Q tte lens. The fibexr fn te Ciliary hooky accomplish this, tlattening ov itt tox. âening tt lLnx for distant @ neay Objects, Berpectiv. â The dittance between the Cones te Ln and ta setina along the visual aris th OpprOxi mately ltr, The Younge 4 tocol dangths is OPPO rrncely l4mm to limm, the tattey taking Place when txs } 1 #româ> The above tiquee (Uustrates how to Obtatn Aimerâiong 4 an Image fovmed on ÂŁe ting i Loa h denot het nt 4g dat object 100 1% In Sh, Felling image, h= Q-Srorn âte. Brightness, Adaptation and DiscatrnedĂ©t ination on | Âą The Mange light Intensity level, i-eur important | to whith th human Visual tem can adapt ff Cnopmous - On the order 10°. #I0m the ACotopic treerhold to the glave Umit, Experimental evickenee indicals Mat subjective befg htrex Cfntenstty as PercbĂ©vedt by the human visual System) & a logan. - thmic function Ma tight Intensity Incident on the ae Fg ae, cu plot 5 Ught intensity Versus Subjec- âtive brightness , (Uustrates thts Chava cari Atics, Glare Umit - 3 RS (gle 32 dig 0 uy Suotopic {] arcaholt WY log 3 lrntansity The tong Jolid Cusve sepresents ta, van ⏠QD intensitieg to Whith the visual Suaten Can Adapt. In Protops « IC Viston alone, the range ts About 10% The transition trom Phetopin to #EAESBIA 4cotopic to Photopic Vis~on W qroderad over Le approximate Fange feom 0-001 anc 041 millilambert (-3 to -ImL fn SMe tog scot), a tt, double Pranches 9 the adap. -tation Ctitrve in thts Fonge Shoo, Two phenomenon Uarsly demonttralis thet percatved befahtret, th not @ Simple function g intensity. The Jtxst 6 based on the fact that um Vigual Syste tends, to Underthoot @ overshoot asouncl the bounderry 3 regions 4 dijlerent intensities. Below Pique Ahows a example } thls Phenomenon, Actual, ? mtev ty we Math Rewctivet band eye intennity. The Colove thak tumant Percetve fa on objeck ae, dele vanined te neluve of the light aeflected From the object. A body Mak vef Luks Light elab ively. Lalanced Ă©n aN visible wosisalinats.s appeerh Utube âto the obseqver. ithe withouk Glor & Caled nono chromatic or achromatic Light. The wy feohure of menodrromalic Light &% intensity. She tntensity of monochvormatic ght perceived bo vary from black b fy Âą fenally & white, She rm gray dh 5 ted easily Lo denote mene hronebve Enbeensity. Chromakie Ceolo1â) Aight Spans the @lecoo magnebic ntergy Spectrum from ap Proxim ably O43 ÂŁ0 OF9uUm. Se three bane Quantities of Chromabie sig be one, a Hadiance : Tek th the btal amount of cnergy thak f lows from the light Source. Cwatts) by AumĂ©nance; GL Giv& a mehure of te amount of cakgy that (flew fer tc Liptet Semee) om observer Can perceive from a light Source. (unit - Lumens (Ln) e7 Brig Ener Âą ft uh a Subjective desevip tor of light perception that Practically fon Possible bo i eabure. YALA AZAZAZ AIOAIACZ COGLARD TONOAG BAA Somage agqutsition iad a Single. Senkog- Example + Photo diodes ; Leg? cs A gaeen ED ofp will be Slronger por green light thaw a other Com ponents in the vizeple Specbrum. Anis th accomplished means of green Cpaxs) filter. in front of we Len Sento). ww) generate a 2D bmage uring a Single Sensor, there ob bo be relakive displacement: tm both hosiqautel GD Âą Voubkical (y) dereckigus âbeween Me Sonsor f Ma 472 bo be Ă©maged. t felon (: Senior. G Ss Kothtion . son a K âââ? âAinear motion.» a One fmege lene ouk Per tnereoent of rotation and full GnevemenÂź dinear displacement of Sasor from left & Tight. A fiben negakive th enounted onko « drum whose emechanteal Yotution Daovides displacement fm one dimensĂ©on. A Single Seusor t% mounted om « load Screw the. Provides yuskion @n SE Perpendicular divectien. Advautang ds ° 17 leon expensive (fn Cripensise ) ay Derevi des ar i veSolukiÂąn fenage. 4 Dibedweustage . Slow Precess, Other eoramples are , Miao demktlometers 1- A flak bed with the Aensor ewoving an boo lmear directions . Image AegquĂ©sction wy Benhor Strips. In this arrangement the Bk ip Provides iain 2 te Clements im ome direction, Motion Derpendi cular Lo Abrip Parovicles sbenogiing in te Olter dĂ©iveckion. Nas type of Semhorh WL made up of Ho00 of more in ling hensorb. Other Applications ares ay Com prutentyed Oxtol Fomegraphy (cat] â Magnebie Resonance EmagĂ©ng Cmas] â? Positron Cm ÂŁS5 tor Tomgaap hy. Cer) Jrvage acyl action valng Senses arrays, Edementasy Senhorh ave A77%an ed in the form of a BD - array, leads to Senhoy arrays. Gg:4 Eleckoormaqnekfe g ultrasonic Sensin deuied. a Digital Cameras [ cep Aarau typically] Acres Semsorh Lypically heve 000% Ho00 Cbemrrts or more. Advantages 1 + Motion of Seton ÂŁ3 mek mecersfany. # Nothe reduction ÂŁ4 achieved fy Enkegaakiog 4p light: Segeral wath raguk Lo time. Digital triage cccguĂ©attion proces Illumination (energy) FN _ EEEECECEEoe ee Output (digitized) image (Internal) image plane | Scene element * Tiumination Source Ppaopets + ed energy oma Boome erent ( obfeck & be rae Some Dart of enengy being reflected fom Scene omen. A Tenaga System Collects he veftected lt 4 from the object Âą Joos tt onto an brage- plane. ustuith veh Colnetdent with the aA She Sensor avaay, the focal plume. of lenh , Dreduces op Proportional to dntegoal of the light zecetved at cath Sensor. # ohnadog 4 digital Clreuttry f Emaging System Produces as Âą dig tal tage CSignals) vapectively. A dimple mage formation Model. Ay bemage &% denoted a @ dimensional. function of the for fy), The amplitude of f? ot ey th uM Positive Beadar qoukte, usbose value Lb | dekeymined ty the Source 1p fmage. (2 Devel lnktanity volue depends on Source of emage. in other words, intensity valu are Prrofortional to energy vedbluked oy the Source. fey) must %& non yoro Âą finite. Le 0< flx,ye oo ([ftrel valuss ave mon ? $ finite) ae She function fos) th Characceriged ty 47 filuemination â» ÂŁ Ge, y) a oy Reflectance â âVCs, 4)