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Biometrics & Biostatistics International Journal

Research Article Volume 7 Issue 6

Ram Awadh distribution with properties and applications

Kamlesh Kumar Shukla

Department of Statistics, Eritrea Institute of Technology, Eritrea

Correspondence: Kamlesh Kumar Shukla, Department of Statistics, College of Science, Eritrea Institute of Technology, Asmara, Eritrea

Received: September 29, 2018 | Published: November 16, 2018

Citation: Shukla KK. Ram Awadh distribution with properties and applications. Biom Biostat Int J. 2018;7(6):515-523. DOI: 10.15406/bbij.2018.07.00254

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Abstract

In this paper, a new one parameter life lime distribution has been proposed and named Ram Awadh distribution. Its moments and moments based measures have been derived. Statistical properties including stochastic ordering, mean deviations, Bonferroni and Lorenz curves, order statistics, Renyi entropy and stress–strength measure have been discussed. Simulation study of proposed distribution has also been discussed. For estimating its parameter method of moments and method of maximum likelihood have been discussed. Goodness of fit of Ram Awadh distribution has been presented and compared with other lifetime distributions of one parameter. It was found superior than other one parameter life time distributions.

Keywords: moments, reliability measures, stochastic ordering, mean deviation, bonferroni and lorenz curves, order statistics, renyi entropy measure, estimation of parameters, goodness of fit

Introduction

One parameter new life time distribution having parameters λ is defined by its pdf

f(x;λ)=λ6λ6+120(λ+x5)eλx    ;x>0,  λ>0  (1.1)

We would name pdf (1.1) Ram Awadh distribution" which is a mixture of two–component, exponential distribution having scale parameter and gamma distribution having shape parameter 6 and scale parameter λ, and their mixing proportions of λ5(λ6+120) and 120(λ6+120) respectively.

f2(x;λ)=pg1(x;λ)+(1p)g2(x;λ,6)

Where p=λ5(λ6+120),g1(x)=λeλx and g2(x)=λ6x5eλx120

The corresponding cumulative distribution function (cdf) of (1.1) is given by

F(x;λ)=1[1+λx(λ4x4+5λ3x3+20λ2x2+60λx+120)λ6+120]eλx   ;x>0,λ>0  (1.2)

The main objective of this paper is to propose a new life time distribution, which may be flexible than other distributions of one parameter proposed by different researchers. Ghitany et al.,1 reported in their paper that Lindley is superior to exponential distribution with reference to data relating to waiting time before service of the bank customers. One parameter lifetime distributions namely Pranav, Ishita, Akash, Shanker, Sujatha and Lindley distributions are proposed by Shukla,2 Shanker & Shukla,3 Shanker,4 Shanker,5 Shanker6 and Lindley7 respectively and applied on biological and engineering data. Statistical properties, estimation of parameter and application of these lifetime distributions have been discussed in the respective papers. It is observed the superiority of proposed distribution over above mentioned distributions, which can be seen in section–10.

In this paper, new one parameter life time distribution has been proposed and named Ram Awadh distribution. Its raw moments and central moments have been obtained and coefficients of variation, skewness, kurtosis and index of dispersion have been discussed. Its hazard rate function, mean residual life function, stochastic ordering, mean deviations, Bonferroni and Lorenz curves, order statistics , Renyi entropy measure and stress – strength have been discussed. Both the method of moments and the method of maximum likelihood have been discussed for estimating the parameter of Ram Awadh distribution. A simulation study of distribution has also been carried out. The goodness of fit of the proposed distribution has been presented and compared with other lifetime distributions of one parameter.

Graphs of the pdf and the cdf of Ram Awadh distributionn for varying values of parameter are presented in Figure 1&2.

Figure 1 Pdf plots of Ram Awadh distribution for varying values of parameter λ.

Figure 2 Cdf plots of Ram Awadh distribution for varying values of parameter λ.

Statistical constants

The rth moment about origin of Ram Awadh distribution can be obtained as

μr=r![λ6+(r+1)(r+2)(r+3)(r+4)(r+5)]λr(λ6+120)  ;r=1,2,3,...  (2.1)

Thus the first four moments about origin of Ram Awadh distribution are given by

μ1=λ6+720λ(λ6+120),μ2=2(λ6+2520)λ2(λ6+120)

μ3=6(λ6+6720)λ3(λ6+120), μ4=24(λ6+15120)λ4(λ6+120)

And central moments of Ram Awadh distribution are obtained as follows:

μ2=(λ12+3840λ6+86400)λ2(λ6+120)2

μ3=2(λ18+12960λ12172800λ6+1036800)λ3(λ6+120)3

μ4=9(λ24+25280λ18+2054400λ12+271872000λ6+3317760000)λ4(λ6+120)4

The coefficient of variation (C.V), coefficient of skewness (β1), coefficient of kurtosis (β2) and index of dispersion (γ) of Ram Awadh distribution are calculated as

C.V=σμ1=(λ12+3840λ6+86400)(λ6+720)

β1=μ3μ2=2(λ18+12960λ12172800λ5+1036800)(λ12+3840λ6+86400)3/2

β2=μ4μ2=9(λ24+25280λ18+2054400λ12+271872000λ6+3317760000)(λ12+3840λ6+86400)2

γ=σ2μ1=(λ12+3840λ6+86400)λ(λ6+120)(λ6+720)

The value of index of dispersion will be one at . To study the nature of C.V, β 1 , β 2 , and of Ram Awadh distribution, graphs of C.V, β 1 , β 2 , and of Ram Awadh distribution have been drawn for varying values of the parameter and presented in Figure 3.

Figure 3 CV, CS, CK and Index of dispersion of Ram Awadh distribution.

Reliability measures

There are two important reliability measures namely hazard rate function and mean residual life function. Let X be a continuous random variable with pdf f(x) and cdf F(x) . The hazard rate function and the mean residual life function of are respectively defined as

h(x)=limΔx0P(X<x+Δx|X>x)Δx=f(x)1F(x)   (3.1)

and  m(x)=E[Xx|X>x]=11F(x)x[1F(t)]  dt   (3.2)

The corresponding h(x) and m(x) of Ram Awadh distribution (1.1) are as follows:

h(x)=λ6(λ+x5)(λ5x5+5λ4x4+20λ3x3+60λ2x2+120λx+λ6+120)   (3.1)

and m(x)=1(λ5x5+5λ4x4+20λ3x3+60λ2x2+120λx+λ6+120)x(λ5t5+5λ4t4+20λ3t3+60λ2t2+120λt+λ6+120)eλtdt

=(λ5x5+10λ4x4+60λ3x3+240λ2x2+600λx+λ6+720)λ(λ5x5+5λ4x4+20λ3x3+60λ2x2+120λx+λ6+120)   (3.4)

It can be verified that h(0)=λ7λ6+120=f(0) and m(0)=λ6+720λ(λ6+120)=μ1.

The graphs of h(x) and m(x) of Ram Awadh distribution for varying values of parameter are presented in Figure 4 & 5.

Figure 4 h(x) Plots of Ram Awadh distribution for varying values of λ.

Figure 5 m(x) Plots of Ram Awadh distribution for varying values of λ.

Stochastic orderings

For judging the comparative behavior of continuous distribution, it is important tool.

 A random variable X is said to be smaller than a random variable in the

  • Stochastic order if for all (XstY) if FX(x)FY(x) for all  x
  • Hazard rate order if for all (XstY) if hX(x)hY(x) for all  x
  • Mean residual life order if for all (XmrlY) if mX(x)mY(x) for all  x
  • Likelihood ratio order if decreases in (XmrlY) if fX(x)fY(x) for all  x.

The following results due to The following results due to Shaked & Shanthikumar8 are well known for establishing stochastic ordering of distributions.

XlrYXhrYXmrlY                    XstY

The Ram Awadh distribution is ordered with respect to the strongest "likelihood ratio ordering" as established in the following theorem:

Theorem: Let and Ram Awadh distribution and respectively. If then and hence , and .

Proof: We have

fX(x;λ1)fY(x;λ2)=λ1(λ2+120)λ2(λ1+120)  e(λ1λ2)x; x>0

fX(x;λ1)fY(x;λ2)=λ1(λ2+120)λ2(λ1+120)  e(λ1λ2)x; x>0

Now lnfX(x;λ1)fY(x;λ2)=ln[λ1(λ2+120)λ2(λ1+120)]+ln(λ1+x5λ2+x5)(λ1λ2)x

This gives ddxlnfX(x;λ1)fY(x;λ2)=2(λ1+λ2)(λ1+x5)(λ2+x5)(λ1λ2)

Thus if θ1>θ2, ddxlnfX(x;θ1)fY(x;θ2)<0. This means that XlrY and hence XhrY, XmrlY and XstY.

Mean deviations

The mean deviation about mean and median defined by

δ1(X)=0|xμ|f(x)dx and δ2(X)=0|xM|f(x)dx respectively, where μ=E(X) and M=Median (X). The measures δ1(X) and δ2(X) can be calculated using the following simplified relationships

δ1(X)=0μ(μx)f(x)dx+μ(xμ)f(x)dx

=μF(μ)0μxf(x)dxμ[1F(μ)]+μxf(x)dx

=2μF(μ)2μ+2μxf(x)dx

=2μF(μ)20μxf(x)dx

and δ2(X)=0M(Mx)f(x)dx+M(xM)f(x)dx

=MF(M)0Mxf(x)dxM[1F(M)]+Mxf(x)dx

=μ+2Mxf(x)dx

=μ20Mxf(x)dx   (5.2)

Using pdf (1.1) and the mean of Ram Awadh distribution, it can be written as:

0μxf(x;λ)dx=μ{λ7μ+λ6(μ6+1)+6λ4μ4(λμ+5)+120μλ2(λμ+5)+120λ2μ2(λμ+3)+720(λμ+1)}eλμλ(λ6+120)   (5.3)

0Mxf(x;θ)dx=μ{λ7M+λ6(M6+1)+6λ4M4(λM+5)+120Mλ2(λM+5)+120λ2M2(λM+3)+720(λM+1)}eλMλ(λ6+120)   (5.4)

Using expressions from (5.1), (5.2), (5.3), and (5.4), the mean deviation about mean, δ1(X) and the mean deviation about median, δ2(X) of Ram Awadh distribution are obtained as

δ1(X)=2{λ5μ5+10λ3μ3(λμ+6)+120λμ(2λμ+5)+(λ6+720)}eλμλ(λ6+120)   (5.5)

δ2(X)=2{λ7M+λ6(M6+1)+6λ4M4(λM+5)+120Mλ2(λM+5)+120λ2M2(λM+3)+720(λM+1)}eλMλ(λ6+120)μ   (5.6)

Bonferroni and lorenz curves

It was given by Bonferron,9 and Bonferroni and Gini indices have applications not only in economics to study income and poverty, but it has also in many applications in different fields, such as demography, insurance and medicine. It can be defined as

B(p)=1pμ0qxf(x)dx=1pμ[0xf(x)dxqxf(x)dx]=1pμ[μqxf(x)dx] (6.1)

L ( p ) = 1 μ 0 q x f ( x ) d x = 1 μ [ 0 x f ( x ) d x q x f ( x ) d x ] = 1 μ [ μ q x f ( x ) d x ]  (6.2)

respectively or equivalently

B(p)=1pμ0pF1(x)dx (6.3)

L(p)=1μ0pF1(x)dx (6.4)

respectively, where μ=E(X) and q=F1(p).

The Bonferroni and Gini indices are thus defined as

B=101B(p)dp (6.5)

and G=1201L(p)dp (6.6)

respectively.

Using pdf of Ram Awadh distribution (1.1), it can be written

qxf(x;λ)dx={λ7q+λ6(q6+1)+6λ4q4(λq+5)+120qλ2(λq+5)+120λ2q2(λq+3)+720(λq+1)}eλqλ(λ6+120) (6.7)

Now using equation (6.7) in (6.1) and (6.2),

B(p)=1p[1{λ7q+λ6(q6+1)+6λ4q4(λq+5)+120qλ2(λq+5)+120λ2q2(λq+3)+720(λq+1)}eλq(λ6+720)] (6.8)

and L(p)=1{λ7q+λ6(q6+1)+6λ4q4(λq+5)+120qλ2(λq+5)+120λ2q2(λq+3)+720(λq+1)}eλq(λ6+720) (6.9)

Now using equations (6.8) and (6.9) in (6.5) and (6.6), the Bonferroni and Gini indices of Ram Awadh distribution are thus given as

B=1{λ7q+λ6(q6+1)+6λ4q4(λq+5)+120qλ2(λq+5)+120λ2q2(λq+3)+720(λq+1)}eλq(λ6+720) (6.10)

G=2{λ7q+λ6(q6+1)+6λ4q4(λq+5)+120qλ2(λq+5)+120λ2q2(λq+3)+720(λq+1)}eλq(λ6+720)1 (6.11)

Order statistics and renyi entropy measure

Order statistics

Let X1,X2,...,Xn be a random sample of size n from Ram Awadh distribution (1.1). Let X(1)<X(2)<  ...  <X(n) denote the corresponding order statistics. The pdf and the cdf of the th order statistic, say Y=X(k) are given by

fY(y)=n!(k1)!(nk)!Fk1(y){1F(y)}nkf(y)

=n!(k1)!(nk)!l=0nk(nkl)(1)lFk+l1(y)f(y)

and FY(y)=j=kn(nj)Fj(y){1F(y)}nj

=j=knl=0nj(nj)(njl)(1)lFj+l(y)

respectively, for k=1,2,3,...,n.

Thus, the pdf and the cdf of kth order statistic of Ram Awadh distribution (1.1) are obtained as

fY(y)=n!λ6(1+x5)eλx(λ6+120)(k1)!(nk)!l=0nk(nkl)(1)l

                        ×[1{λx(λ4x4+5λ3x3+20λ2x2+60λx+120)}eλxλ6+120]k+l1

and FY(y)=j=knl=0nj(nj)(njl)(1)l[1{λx(λ4x4+5λ3x3+20λ2x2+60λx+120)}eλxλ6+120]j+l

Entropy measure

Entropy of a random variable X is a measure of variation of uncertainty. A popular entropy measure is Renyi entropy. If X is a continuous random variable having probability density function f(.), then Renyi entropy is defined as

TR(γ)=11γlog{fγ(x)dx}

where γ>0   and   γ1.

Thus, the Renyi entropy for Ram Awadh (1.1) can be obtained as

=11γlog[0λ6γ(λ6+120)γ(λ+x5)γeλγxdx]

=11γlog[0λ7γ(λ6+120)γ(x5)γj=0(γj)(x5λ)jeλγxdx]

=11γlog[j=0(γj)λ7γ(λ6+120)γ0eλγxx5j+11dx]

=11γlog[j=0(γj)λ7γ(λ6+120)γΓ(5j+1)(λγ)5j+1]

=11γlog[λ7γ5j1(λ6+120)γj=0(γj)Γ(5j+1)(γ)5j+1]

A simulation study

This process consists in generating N=10,000 pseudo–random samples of sizes 20, 40, 60, 80 and 100 from Ram Awadh distribution. Acceptance and rejection method has been used for this study. Average bias and mean square error of the MLEs of the parameter λ are estimated using the following formulae
Average Bias = 1Nj=1n(λ^jλ)  , MSE= 1Nj=1n(λ^jλ)2

The following algorithm can be used to generate random sample from Ram Awadh distribution.

Algorithm

Rejection method: To simulate from the density fX, it is assumed that envelope density h from which it can simulate, and that have some k< such that supxfX(x)h(x)k Simulate X from h.

  1. Generate Y~U(0,kh(X) , where k=λ6(λ6+120)
  2. If Y<fX(x) then return X, otherwise go back to step 1.

The average bias (mean square error) of simulated estimate of parameter λ for different values of n and λ are presented in Table 1.

Figure 6 Estimated mean squared error of the MLEs for different values of λ and n.

n

Parameter λ

0.05

0.5

1

2

20

0.08744(0.152915)

0.08775(0.154001)

0.081133(0.13165)

0.07470(0.11161)

40

0.041025(0.067322)

0.040931 (0.06701)

0.036754(0.05403)

0.032039(0.04106)

60

0.027958(0.04690)

0.027833(0.046482)

0.025377 (0.03864)

0.022434(0.03019)

80

0.02082(0.034680)

0.020767(0.034504)

0.018765(0.028171)

0.016455(0.02166)

100

0.016428(0.026989)

0.016368(0.026792

0.014731(0.021702)

0.012791(0.01636)

Table 1 Average bias (mean square error) of the simulated estimates of parameter θ

The graphs of estimated mean square error of the maximum likelihood estimate (MLE) for different values of parameter λ and n have been shown in Figure 6.

Stress–strength reliability

It explains the life of a component which has random strength X that is subjected to a random stress Y. When the stress applied to it exceeds the strength, the component fails instantly and the component will function adequately till X>Y. Therefore, R=P(Y<X) is a measure of component reliability.

 Let X and Y be independent strength and stress random variables having Ram Awadh (1.1) with parameter λ1  and λ2  respectively. Then the stress–strength reliability R can be obtained as

R=P(Y<X)=0P(Y<X|X=x)fX(x)dx

=0f(x;λ1)  F(x;λ2)dx

=1λ16[λ2+10λ215λ1+45λ214λ12+120λ213λ13+210λ212λ14+(252λ15+120)λ211+(210λ16+600λ1+720)λ210+(120λ17+1200λ12+5400λ1)λ29+(1200λ13+18600λ12+45λ18)λ28+10λ13(λ16+60λ1+3900)λ27+λ14(λ16+120λ1+55320)λ26+(55440λ15+6652800)λ25+(39600λ16+4752000λ1)λ24+(19800λ17+2376000λ12)λ23+(66600λ18+792000λ13)λ22+(1320λ19+158400λ14)λ2+120λ110+14400λ15](λ1+120)(λ2+120)(λ1+λ2)11

Parameters estimation

Method of moments estimates (MOME) of parameters

Equating population mean of Ram Awadh distribution to the corresponding sample mean, MOME λ^ of λ is the solution of following non–linear equation λ7x¯+120λx¯(λ6+720)=0

λ7x¯+120λx¯(λ6+720)=0 (10.1)

Maximum likelihood estimates (MLE) of parameters

Let (x1,x2,x3,  ...  ,xn) be a random sample of size n from Ram Awadh (1.1)). The likelihood function, of Ram Awadh distribution is given by

L=(λ6λ6+120)ni=1n(λ+xi)enλx¯

and so its natural log likelihood function is thus obtained as

lnL=nln(λ6λ6+120)+i=1nln(λ+xi)nλx¯

The maximum likelihood estimates (MLEs) of to the solution of the following non–linear equation

lnLλ=6nλ6nλ5(λ6+120)+1(λ+x5)nx¯=0 (10.2)

where is the sample mean. Equation (10.2) can solve directly for parameter using Newton–Raphson method. Its parameter is estimate using R–software.9,10

Illustrative example

Data set 1:

This data is related with behavioral sciences, collected by N. Balakrishnan, Victor Leiva & Antonio Sanhueza,11 the detailed about the data are given in Balkrishnan et al.,12 The scale “General Rating of Affective Symptoms for Preschoolers (GRASP)” measures, which are:

19(16) 20(15) 21(14) 22(9) 23(12) 24(10) 25(6) 26(9) 27(8) 28(5) 29(6) 30(4) 31(3) 32(4) 33 34 35(4) 36(2) 37(2) 39 42 44

Data set 2: This data set is the strength data of glass of the aircraft window reported by Fuller et al.,12 18.83 20.8 21.657 23.03 23.23 24.05 24.321 25.5 25.52 25.8 26.69 26.77 26.78 27.05 27.67 29.9 31.11 33.2 33.73 33.76 33.89 34.76 35.75 35.91 36.98 37.08 37.09 39.58 44.045 45.29 45.381

Data Set 3: The following data represent the tensile strength, measured in GPa, of 69 carbon fibers tested under tension at gauge lengths of 20mm (Bader and Priest)13:

1.312 1.314 1.479 1.552 1.700 1.803 1.861 1.865 1.944 1.958 1.966 1.997 2.006 2.021 2.027 2.055 2.063 2.098 2.140 2.179 2.224 2.240 2.253 2.270 2.272 2.274 2.301 2.301 2.359 2.382 2.382 2.426 2.434 2.435 2.478 2.490 2.511 2.514 2.535 2.554 2.566 2.570 2.586 2.629 2.633 2.642 2.648 2.684 2.697 2.726 2.770 2.773 2.800 2.809 2.818 2.821 2.848 2.880 2.954 3.012 3.067 3.084 3.090 3.096 3.128 3.233 3.433 3.585 3.858

For the above three data sets, Ram Awadh distribution has been fitted along with one parameter exponential, Lindley and Akash, Shanker, Sujatha, Ishita and Pranav distribution. The pdf and cdf of one parameter fitted distributions are presented in Table 2. The ML estimates, values of and K–S statistics of the fitted distributions are presented in Table 3. As we know that the best distribution corresponds to the lower values of and K–S.

Profile plot of parameter and fitted plot for dataset–1, 2 and 3 are presented in Figures 7–9 respectively. From the graph, it is observed that Ram Awadh distribution is closer to observed dataset in comparison to other distributions of one parameter.

Figure 7 Profile of parameter and fitted probability plots for data set-1.

Figure 8 Profile of parameter and fitted probability plots for data set-2.

Figure 9 Profile of parameter and fitted probability plots for data set-3.

Distribution

pdf

Cdf

Pranav

f(x;λ)=λ4λ4+6(λ+x3)eλx

F(x;λ)=1[1+λx(λ2x2+3λx+6)λ4+6]eλx

Akash

f(x,λ)=λ3λ2+2(1+x2)eλx

F(x,λ)=1[1+λx(λx+2)λ2+2]eλx

Shanker

f(x,λ)=λ2λ2+1(λ+x)eλx

F(x,λ)=1[1+λxλ2+1]eλx

Sujatha

f(x;λ)=λ3λ2+λ+2(1+x+x2)eλx

F(x,λ)=1[1+λx(λx+λ+2)λ2+λ+2]eλx

Ishita

f(x;λ)=λ3λ3+2(λ+x2)eλx

F(x,λ)=1[1+λx(λx+2)λ3+2]eλx

Lindley

f(x;λ)=λ2λ+1(1+x)eλx

F(x;λ)=1[λ+1+λxλ+1]eλx

Exponential

f(x;λ)=λeλx

F(x;λ)=1eλx

Table 2 The p.d.f. and the c.d.f. of fitted distributions

Data set

Model

Parameter

-2ln L

AIC

BIC

K-S

Estimate

Statistic

Data 1

RamAwadh

0.240358

899.93

901.93

904.53

0.308

Pranav

0.160222

945.03

947.03

948.94

0.362

Ishita

0.120083

980.02

982.02

984.62

0.399

Sujatha

0.117456

985.69

987.69

990.29

0.403

Akash

0.11961

981.28

983.28

986.18

0.4

Shanker

0.079746

1033.1

1035.1

1037.99

0.442

Lindley

0.077247

1041.64

1043.64

1046.54

0.448

Exponential

0.04006

1130.26

1132.26

1135.16

0.525

Data2

RamAwadh

0.194733

223.07

225.07

227.31

0.197

Pranav

0.129818

232.77

234.77

236.68

0.253

Ishita

0.097325

240.48

242.48

244.39

0.298

Sujatha

0.09561

241.5

243.5

245.41

0.302

Akash

0.097062

240.68

242.68

244.11

0.266

Shanker

0.064712

252.35

254.35

255.78

0.326

Lindley

0.062988

253.99

255.99

257.42

0.333

Exponential

0.032455

274.53

276.53

277.96

0.426

Data 3

RamAwadh

2.009849

188.77

190.77

193

0.261

Pranav

1.225138

217.12

219.12

221.03

0.303

Ishita

0.931571

223.14

225.14

227.05

0.33

Sujatha

0.936119

221.6

223.6

225.52

0.364

Akash

0.964726

224.28

226.28

228.51

0.348

Shanker

0.658029

233.01

235.01

237.24

0.355

Lindley

0.659

238.38

240.38

242.61

0.39

Exponential

0.407941

261.74

263.74

265.97

0.434

Table 3 MLE"s, -2ln L, AIC, BIC, K-S Statistics of the fitted distributions of data-sets 1-3

Conclusion

In this paper, a new one parameter lifetime distribution named Ram Awadh distribution has been proposed. Its mathematical properties including moments, measure of dispersion, hazard rate function, mean residual life function, stochastic ordering, mean deviations, order statistics, Bonferroni and Lorenz curves, and stress–strength reliability have been discussed. Simulation study of Ram Awadh distribution has also been discussed. The method of moments and the method of maximum likelihood estimation have been derived for estimating the parameter. In the last, three numerical examples of real lifetime data sets have been illustrated to test the goodness of fit of the Ram Awadh distribution. Its fit was found satisfactory over exponential, Lindley, Sujatha, Ishita, Akash , Shanker and Pranav distribution.

Note: The paper is named Ram Awadh distribution in the name of my Father Shri Ram Awadh Shukla.

Acknowledgements

None.

Conflict of interest

Author declares that there is no conflict of interest.

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