Analyzing effect of a secondary cognitive load task on a primary executive task

What is claimed is: 1. A processor implemented method, comprising: assigning, by one or more hardware processors, a primary executive task to a subject, wherein the primary executive task is generation of random numbers by the subject to obtain human generated random numbers; digitizing, by the one or more hardware processors, the human generated random numbers into a first random sequence (RS) in a baseline by concatenating the human generated random numbers until: capture of a specific number of the generated random numbers, or capture of the generated random numbers in a specific time period, wherein the first RS in the baseline is digitized after a first baseline period, and the first baseline period is a time period after the generation of the random numbers; generating, after the primary executive task, a second RS in a low load (LL) and a third RS in a high load (HL), by the one or more hardware processors, by imposing a secondary cognitive load task in a form of: a low cognitive load inducing task on the subject, and a high cognitive load inducing task on the subject, wherein the secondary cognitive load task includes auditory addition of a plurality of auditory digits, the low cognitive load inducing task includes the auditory addition of a plurality of first specific auditory digits of the plurality of auditory digits, the high cognitive load inducing task includes the auditory addition of a plurality of second specific auditory digits of the plurality of auditory digits, a count of the plurality of second specific auditory digits is greater than a count of the plurality of first specific auditory digits, an auditory digit of the plurality of auditory digits is presented at a rate of 1 auditory digit per 3 seconds for the low cognitive load inducing task, the auditory digit of the plurality of auditory digits is presented at a rate of 1 auditory digit per 4 seconds for the high cognitive load inducing task, the low cognitive load inducing task is preceded by a first pause for a second baseline period, wherein the second baseline period is a time period after the digitization of the RS in the baseline, the high cognitive load inducing task is preceded by a second pause for a third baseline period, wherein the third baseline period is a time period after completion of the low cognitive load inducing task, and each of the second baseline period and the third baseline period allows the subject to relax; receiving, by the one or more hardware processors, gaze data and pupillometry data associated with the subject, from an eye tracker, wherein each of the gaze data and the pupillometry data is specific data that is received during performance of both the primary executive task and the secondary cognitive load task by the subject; extracting gaze related fixation patterns, by the one or more hardware processors, from the received gaze data by separating fixation points of the gaze data and saccade points of the gaze data based on point-to-point velocities in the gaze data, wherein the fixation patterns are extracted for each of the first RS in the baseline, the second RS in the LL, and the third RS in the HL, the fixation points include a plurality of points of the gaze data having a first velocity that is lesser than a specific threshold, and the saccade points include a second plurality of points of the gaze data having a second velocity that is equal to or greater than the specific threshold; and computing, for each of the first RS in the baseline, the second RS in the LL, and the third RS in the HL, by the one or more hardware processors, a load index (A) by calculating a ratio of: a product of summation of a length of repeating fixation of the fixation patterns of the extracted gaze data and a total length of random sequence, and a total number of fixations of the gaze data, wherein the load index indicates an effect of the secondary cognitive load task on the primary executive task, and a value of the load index is directly proportional to the effect of the secondary cognitive load task on the primary executive task. 2. The processor implemented method of claim 1 , wherein digitizing the human generated random numbers further comprises: positioning a fixational cross ‘+’ at a center of a white screen for the first baseline period; displaying a plurality of digits of a specific font size in a 3×3 matrix on the white screen; and concatenating the human generated random numbers based on randomly clicked digits of the plurality of displayed digits by the subject. 3. The processor implemented method of claim 1 , wherein an interval of each of the first baseline period, the second baseline period, and the third baseline period is equal. 4. The processor implemented method of claim 1 , further comprising: computing a first deviation from randomness of the first RS in the baseline, the second RS in the LL, and the RS in the HL using one or more metrics, wherein the one or more metrics includes Coupon (Cn) test, a Gap (Gp) test, a Poker (Pk) test, a Repetitions (Rp), a Series (Sr), a Variance of digits (VD), a Digram repetitions (DR), a Cluster Ratio (CR), a Random a Number Generator (RNG), and a Turning Point index (TP), wherein the first deviation indicates the effect of the secondary cognitive load task on the primary executive task, and the first deviation is directly proportional to the effect of the secondary cognitive load task on the primary executive task; and comparing the received pupillometry data of the subject with specific pupillometry data of a healthy subject to analyze the effect of the secondary cognitive load task on the primary executive task, wherein a second deviation from the specific pupillometry data indicates the effect of the secondary cognitive load task on the primary executive task. 5. A system, comprising: one or more data storage devices operatively coupled to one or more hardware processors, wherein the one or more data storage devices configured to store instructions for execution by the one or more hardware processors to: assign a primary executive task to a subject, wherein the primary executive task is generation of random numbers by the subject to obtain human generated random numbers; digitize the human generated random numbers into a first random sequence (RS) in a baseline by concatenating the human generated random numbers until: capture of a specific number of the generated random numbers, or capture of the generated random numbers in a specific time period, wherein the first RS in the baseline is digitized after a first baseline period, and the first baseline period is a time period after the generation of the random numbers; generate, after the primary executive task, a second RS in a low load (LL) and a third RS in a high load (HL), by imposing a secondary cognitive load task in a form of: a low cognitive load inducing task on the subject, and a high cognitive load inducing task on the subject, wherein the secondary cognitive load task includes auditory addition of a plurality of auditory digits, the low cognitive load inducing task includes the auditory addition of a plurality of first specific auditory digits of the plurality of auditory digits, the high cognitive load inducing task includes the auditory addition of a plurality of second specific auditory digits of the plurality of auditory digits, a count of the plurality of second specific auditory digits is greater than a count of the plurality of first specific auditory digits, an auditory digit of the plurality of auditory digits is presented at a rate of 1 auditory digit per 3 seconds for the low cognitive load inducing task, the auditory digit of the plurality of auditory digits is presented at a rate of 1 auditory digit per 4 seconds for