Sample size for estimating mean and coefficient of variation in species of crotalarias

TOEBE, MARCOS; MACHADO, LETÍCIA N.; TARTAGLIA, FRANCIELI L.; CARVALHO, JULIANA O. DE; BANDEIRA, CIRINEU T.; CARGNELUTTI FILHO, ALBERTO

doi:10.1590/0001-3765201820170813

ABSTRACT

The objective of this study was to determine the sample size necessary to estimate the mean and coefficient of variation in four species of crotalarias (C. juncea, C. spectabilis, C. breviflora and C. ochroleuca). An experiment was carried out for each species during the season 2014/15. At harvest, 1,000 pods of each species were randomly collected. In each pod were measured: mass of pod with and without seeds, length, width and height of pods, number and mass of seeds per pod, and mass of hundred seeds. Measures of central tendency, variability and distribution were calculated, and the normality was verified. The sample size necessary to estimate the mean and coefficient of variation with amplitudes of the confidence interval of 95% (ACI_95%) of 2%, 4%, ..., 20% was determined by resampling with replacement. The sample size varies among species and characters, being necessary a larger sample size to estimate the mean in relation of the necessary for the coefficient of variation.

Key words:
Crotalaria sp; experimental precision; number of pods; resampling

INTRODUCTION

The species of the genus Crotalaria are used as cover plants in crops rotation systems, with high production of green matter mass and biological nitrogen fixation, contributing to the production of organic matter (Chaudhary 2016CHAUDHARY B. 2016. Traditional cultivation of sunnhemp (Crotalaria juncea) in eastern India. Indian J Agric Sci 86: 369-372.). According to Vargas et al. (2017VARGAS TO, DINIZ ER, PACHECO ALV, SANTOS RHS AND URQUIAGA S. 2017. Green manure-15N absorbed by broccoli and zucchini in sequential cropping. Sci Hortic 214: 209-213.), the residual nitrogen of C. juncea is sufficient for growing broccoli followed by zucchini. Bhandari et al. (2016BHANDARI HR, TRIPATHI MK, CHAUDHARY B AND SARKAR SK. 2016. Sunnhemp breeding: Challenges and prospects. Indian J Agric Sci 86: 1391-1398.) highlight that the C. juncea is an important source of fiber, but that few studies have been developed, being the genetic breeding incipient in this species. C. spectabilis can reduce the incidence of Ralstonia solanacearum in tomato plants (Deberdt et al. 2015DEBERDT P, GOZÉ E, CORANSON-BEAUDU R, PERRIN B, FERNANDES P, LUCAS P AND RATNADASS A. 2015. Crotalaria spectabilis and Raphanus sativus as previous crops show promise for the control of bacterial wilt of tomato without reducing bacterial populations. J Phytopathol 163: 377-385.) and also features low suitability for reproduction of Helicoverpa armigera (Reigada et al. 2016REIGADA C, GUIMARÃES KF AND PARRA JRP. 2016. Relative fitness of Helicoverpa armigera (Lepidoptera: Noctuidae) on seven host plants: a perspective for IPM in Brazil. J Insect Sci 16: 1-5.). According to Machado et al. (2007MACHADO ACZ, MOTTA LCC, SIQUEIRA KMS, FERRAZ LCCB AND INOMOTO MM. 2007. Host status of green manures for two isolates of Pratylenchus brachyurus in Brazil. Nematology 9: 799-805.) and Braz et al. (2016BRAZ GBP, OLIVEIRA JRRS, CONSTANTIN J, RAIMONDI RT, RIBEIRO LM, GEMELLI A AND TAKANO HK. 2016. Plantas daninhas como hospedeiras alternativas para Pratylenchus brachyurus. Summa Phytopathol 42: 233-238.), C. spectabilis , C. breviflora and C. ochroleuca can be used to reduce the population density and management of areas infested with Pratylenchus brachyurus.

When the experiments were carried out, one of the main steps is the definition of the sample size suitable to be used for the evaluation of the effect of treatments, being the same influenced by the desired precision, by characters that will be evaluated, by the variability of the data and the error rate allowed. Sample size is important for the representativeness of the research and the validity of the conclusions (Koumanov 2017KOUMANOV KS. 2017. Sample size determination in horticultural research: an empirical approach. Sci Hort 225: 416-421.). According to Ferreira (2009FERREIRA DF. 2009. Estatística básica, 2nd ed., Lavras: UFLA. ), the resampling with replacement can be used for the sample sizing, being independent of the data probability distribution. This technique has been used in the sample sizing for the estimation of genetic and phenotypic parameters of sugar cane (Leite et al. 2009LEITE MSO, PETERNELLI LA, BARBOSA MHP, CECON PR AND CRUZ CD. 2009. Sample size for full-sib family evaluation in sugarcane. Pesq Agropec Bras 44: 1562-1574.), mean and coefficient of variation (Toebe et al. 2014TOEBE M, CARGNELUTTI FILHO A, BURIN C, CASAROTTO G AND HAESBAERT FM. 2014. Tamanho de amostra para estimação da média e do coeficiente de variação em milho. Pesq Agropec Bras 49: 860-871. ), linear correlation (Cargnelutti Filho et al. 2010, Toebe et al. 2015) and path analysis (Toebe et al. 2017b) in maize and the mean and standard deviation of pepper fruits (Silva et al. 2015SILVA AR, HILÁRIO RF, RÊGO ER, NASCIMENTO NFF, DIAS CTS AND LIMA RP. 2015. A multivariate approach to determine sample size for morphological characterization of pepper fruits. Aust J Crop Sci 9: 1064-1068.). The resampling process was also used in the sampling size of cover plants, as for the estimation of the mean of characters of jack bean and velvet bean seeds (Cargnelutti Filho et al. 2012) and the plastochron in pigeon pea (Cargnelutti Filho et al. 2013).

Specifically in crotalarias, Facco et al. (2017FACCO G ET AL. 2017. Basic experimental unit and plot sizes with the method of maximum curvature of the coefficient of variation in sunn hemp. Afr J Agric Res 12: 415-423.) evaluated the influence of basic experimental units in the estimate of the optimal plot size for the evaluation of fresh mass of C. juncea. Teodoro et al. (2015TEODORO PE, SILVA JÚNIOR CA, RIBEIRO LP, SILVA FA, CORRÊA CCG, ZANUNCIO AS AND TORRES FE. 2015. Sample dimension for estimation of biomass and yield of sunn (Crotalaria juncea L.) and showy rattlebox (C. spectabilis Roth.). J Agron 14: 98-101.) and Toebe et al. (2017aTOEBE M, BANDEIRA CT, FORTES SKG, CARVALHO JO, TARTAGLIA FL, TAMBARA AL AND MELO PJ. 2017a. Dimensionamento amostral e associação linear entre caracteres de Crotalaria spectabilis. Bragantia 76: 45-53.) determined the sample size to estimate the average of characters in C. juncea and C. spectabilis using the Student’s t-distribution. In the study of Teodoro et al. (2015), the sample size oscillated among the levels of precision, variables and between the two species of crotalarias. It is likely that when a larger number of variables and species of this genus are evaluated, changes occur in the recommendation of the sample size. Still, although some theoretical studies (Kelley 2007KELLEY K. 2007. Sample size planning for the coefficient of variation from the accuracy in parameter estimation approach. Behav Res Methods 39: 755-766., Panichkitkosolkul 2009PANICHKITKOSOLKUL W. 2009. Improved confidence intervals for a coefficient of variation of a normal distribution. Thailand Statistician 7: 193-199., Banik et al. 2012BANIK S, KIBRIA BMG AND SHARMA D. 2012. Testing the population coefficient of variation. J Mod Appl Stat Methods 11: 325-335.) and practical studies (Toebe et al. 2014) of sample sizing for the coefficient of variation have been developed, reports in the literature were not found on such information on species of crotalaria. Thus, the objective of this study was to determine the sample size necessary to estimate the mean and coefficient of variation in four species of crotalarias (C. juncea, C. spectabilis, C. breviflora and C. ochroleuca) in precision levels.

MATERIALS AND METHODS

Four tests of uniformity were carried out (blank experiments, i.e., without treatments) in the season of 2014/2015, in the experimental area of the Federal University of Pampa, Campus Itaqui, located in the municipality of Itaqui, State of Rio Grande do Sul, Brazil, in geographic coordinates lat 29°09’S and long 56°33’W and altitude of 74 m. According to the classification of Köppen, the climate of the region is Cfa type, humid subtropical with hot summers and without a defined dry season (Wrege et al. 2011WREGE MS, STEINMETZ S, REISSER JÚNIOR C AND ALMEIDA IR. 2011. Atlas climático da Região Sul do Brasil: Estados do Paraná, Santa Catarina e Rio Grande do Sul. Pelotas: Embrapa Clima Temperado; Embrapa Florestas.), and the soil classified as Haplic Plinthosol (Santos et al. 2013SANTOS HG, ALMEIDA JA, OLIVEIRA JB, LUMBRERAS JF, ANJOS LHC, COELHO MR, JACOMINE PKT, CUNHA TJF AND OLIVEIRA VA. 2013. Sistema brasileiro de classificação de solos, 3rd ed., Brasília: EMBRAPA.).

Each test of uniformity was performed in an area of 65.61 m² (8.1 m in length × 8.1 m width) and was destined to one of the four species of crotalarias (C. juncea, C. spectabilis, C. breviflora and C. ochroleuca). In the four assays of uniformity the fertilizer basis was 25 kg∙ha⁻¹ of N, 100 kg∙ha⁻¹ of P₂O and 100 kg∙ha⁻¹ of K₂O and all the cultural treatments were carried out in a uniform way within the sample area. This standardization for performing of uniformity assays is indicated by Storck et al. (2016STORCK L, GARCIA DC, LOPES SJ AND ESTEFANEL V. 2016. Experimentação Vegetal, 3rd ed., Santa Maria: UFSM, 200 p.).

The seeds of C. juncea, cultivar IAC-KR1, were seeded on 10/18/2014, with spacing between rows of 0.45 m and 27 seeds per meter of row, totaling 60 seeds per m². The seeds of C. spectabilis, common cultivar, were seeded on 10/16/2014, with spacing between rows of 0.45 m and 33 seeds per meter of row, totaling 73 seeds per m². The seeds of C. breviflora, common cultivar, were seeded on 10/17/2014, with spacing between rows of 0.45 m and 33 seeds per meter of row, totaling 73 seeds per m². The seeds of C. ochroleuca, common cultivar, were seeded on 10/20/2014, with spacing between rows of 0.45 m and 44 seeds per meter of row, totaling 98 seeds per m².

In the period from March to June 2015, successive harvests of pods were held, randomly, in each assay of uniformity, in accordance with the productive cycle of each species. For each species (C. Juncea, C. spectabilis, C. breviflora and C. ochroleuca), 1,000 pods were collected and, in each pod, the following characters were evaluated: mass of pod with seeds (MPWS, in g); mass of pod without seeds (MPWOS, in g); length of the pod (LP, in mm); width of the pod (WP, in mm); height of the pod (HP, in mm); number of seeds per pod (NSP, in units); mass of seeds per pod (MSP, in g); and mass of one hundred seeds (MHS, in g). From these data it was calculated the minimum, mean, median, maximum, variance, standard deviation, coefficient of variation, asymmetry and kurtosis values of each character in each species, being checked the normality of the data through the test of Kolmogorv-Smirnov.

For each character of each species of crotalaria, 190 sample sizes were planned, being the smallest sample size of 10 pods and the other sample sizes obtained with addition of five pods. Thus, the sample sizes planned were n = 10, 15, 20, ..., 1,000 pods. For each planned sample size, in each species, 10,000 resamples with replacement were obtained, being that in each resample, the mean (x̅) and the coefficient of variation (CV, in %) of each of the eight characters were estimated. Thus, for each planned sample size, 10,000 estimates of the mean and coefficient of variation for each character were obtained. Based on these 10,000 estimates of each statistic ( x̅ and CV), the percentile 2.5%, the mean and the percentile 97.5% were determined. Afterwards, the amplitude of the confidence interval of 95% was calculated (ACI_95%) by the difference between the percentile 97.5% and the percentile 2.5%.

For the determination of sample size (number of pods) required to estimate the mean of each of the eight characters in each species of crotalaria, maximum limits of ACI_95% were fixed, of 2% (greater precision), 4%, 6%, ..., 20%, (less precision) of mean. Whereas for the determination of sample size required to estimate the coefficient of variation (CV, in %), of each of the eight characters in each species of crotalaria, maximum limits of ACI_95% were fixed of 2% (greater precision), 4%, 6%, ..., 20% (less precision). Then, it was started from the initial sample size (n = 10 pods) and it was considered as appropriate sample size (n) the number of pods from which the amplitude of the confidence interval of 95% (ACI_95%) was less than or equal to the maximum limit established for each level of precision, as already described in previous studies (Cargnelutti Filho et al. 2010, Toebe et al. 2014TOEBE M, CARGNELUTTI FILHO A, BURIN C, CASAROTTO G AND HAESBAERT FM. 2014. Tamanho de amostra para estimação da média e do coeficiente de variação em milho. Pesq Agropec Bras 49: 860-871. , 2015, 2017b). Statistical analyzes were performed with the aid of the program R (R Development Core Team 2017) and the application Microsoft Office Excel^®.

RESULTS AND DISCUSSION

In general, it was found wide variability (difference between maximum and minimum values) of data in eight characters evaluated in four species of crotalarias (C. juncea, C. spectabilis, C. breviflora and C. ochroleuca), which may be justified by the number of pods evaluated (Table I). This wide variability is indicative that the extreme values are included in the sample of 1,000 pods, and this is important for the correct sample dimensioning. For a given character and species, the values of mean and median were similar among themselves, indicating good fit of the data to normal distribution. In this sense, it was found mesokurtic kurtosis in seven, four, seven and seven characters of the species C. juncea, C. spectabilis, C. breviflora and C. ochroleuca, respectively.

Thumbnail

TABLE I
Minimum, mean, median, maximum, variance, standard deviation (SD), coefficient of variation (CV in %), asymmetry, kurtosis and p-value of the test of normality of Kolmogorov-Smirnov to eight characters measured in 1,000 pods of four species of crotalarias - C. juncea, C. spectabilis, C. breviflora and C. ochroleuca - in the season of 2014/15 in Itaqui - RS - Brazil.

It was verified positive and significant asymmetry (p ≤ 0.05) in five, zero, zero and one character and, negative and significant asymmetry (p ≤ 0.05) in one, three, four and two characters, in the species C. juncea, C. spectabilis, C. breviflora and C. ochroleuca, respectively (Table I). The significant deviations of asymmetry observed in 50% of cases can be associated with high sample size used (n = 1,000 pods), since the amplitude of the confidence interval of the asymmetry can be reduced by increasing the size of the sample. Thus, small deviations of asymmetry become statistically significant (Doane and Seward 2011DOANE DP AND SEWARD LE. 2011. Measuring Skewness: A Forgotten Statistic? J Stat Educ 19: 1-18., Wright and Herrington 2011WRIGHT DB AND HERRINGTON JA. 2011. Problematic standard errors and confidence intervals for skewness and kurtosis. Behav Res Methods 43: 8-17.), as already observed in data from corn hybrids (Toebe et al. 2014TOEBE M, CARGNELUTTI FILHO A, BURIN C, CASAROTTO G AND HAESBAERT FM. 2014. Tamanho de amostra para estimação da média e do coeficiente de variação em milho. Pesq Agropec Bras 49: 860-871. ).

The character NSP was the only character that does not fit the normal distribution in the four species evaluated (Table I). It was also not found fit to normal distribution for these characters MSP and MPWOS in C. breviflora and C. ochroleuca, respectively. For the remaining cases, normality of data (p > 0.05) was observed. Considering the large number of evaluations, the wide variability of data, the similarity among the values of mean and median, the predominance of mesokurtic and symmetrical data, the fit to the normal distribution and, also taking into account, the process of sampling sizing via resampling (Ferreira 2009FERREIRA DF. 2009. Estatística básica, 2nd ed., Lavras: UFLA. ), it may be inferred that the database offers reliability for the proposed study, and the sample sizes determined serve as reference for the culture.

In the four species of crotalarias, the coefficient of variation showed lower values in the characters originated from the measurement (LP, WP and HP) in relation to those obtained by counting and weighing (MPWS, MPWOS, NSP, MSP and MHS - Table I). The coefficient of variation ranged between 5.40% and 10.53% for the characters LP, WP and HP assessed in the species C. juncea, C. spectabilis, C. breviflora and C. ochroleuca. For the characters MPWS, MPWOS, NSP, MSP and MHS, the coefficient of variation ranged between 8.83% and 36.31%. Yet the values of CV increased at the order C. spectabilis, C. breviflora, C. ochroleuca and C. juncea. These results suggest a lower sample size for LP, WP and HP compared to other characters and smaller sample size for C. spectabilis, C. breviflora and C. ochroleuca in relation to C. juncea.

In ten characters evaluated in plants of C. spectabilis, Toebe et al. (2017aTOEBE M, BANDEIRA CT, FORTES SKG, CARVALHO JO, TARTAGLIA FL, TAMBARA AL AND MELO PJ. 2017a. Dimensionamento amostral e associação linear entre caracteres de Crotalaria spectabilis. Bragantia 76: 45-53.) verified a coefficient of variation in the range of 7.819% for mass of 100 grains to 55.452% for number of seeds per plant. In C. juncea and C. spectabilis, Teodoro et al. (2015TEODORO PE, SILVA JÚNIOR CA, RIBEIRO LP, SILVA FA, CORRÊA CCG, ZANUNCIO AS AND TORRES FE. 2015. Sample dimension for estimation of biomass and yield of sunn (Crotalaria juncea L.) and showy rattlebox (C. spectabilis Roth.). J Agron 14: 98-101.) observed higher values of coefficients of variation for fresh matter mass, followed by dry matter mass and yield, being observed greater variability for characters evaluated in C. juncea in relation to C. spectabilis, similarly to this study.

For the highest level of precision [amplitude of the confidence interval of 95% (ACI_95%) of 2% of the mean], the sample size ranged between 235 to more than 1,000 pods for C. juncea, between 120 to more than 1,000 pods for C. spectabilis, between 115 to more than 1,000 pods for C. breviflora and between 305 to more than 1,000 pods for C. ochroleuca, depending on the character (Table II). These results indicate that to estimate the mean of various characters more than one thousand pods should be evaluated, if the researcher chooses to use this level of precision. In these cases, it would be recommended study of sample sizing with simulation of sample sizes greater those stipulated in the present study. Using semi-amplitude of confidence interval of 95% of 1% of the mean by the Student’s t test distribution, Teodoro et al. (2015TEODORO PE, SILVA JÚNIOR CA, RIBEIRO LP, SILVA FA, CORRÊA CCG, ZANUNCIO AS AND TORRES FE. 2015. Sample dimension for estimation of biomass and yield of sunn (Crotalaria juncea L.) and showy rattlebox (C. spectabilis Roth.). J Agron 14: 98-101.) verified the need for evaluation from 1,108 to 8,510 plants, depending on the character and the species of crotalaria (C. juncea or C. spectabilis). In this range of precision, Toebe et al. (2017aTOEBE M, BANDEIRA CT, FORTES SKG, CARVALHO JO, TARTAGLIA FL, TAMBARA AL AND MELO PJ. 2017a. Dimensionamento amostral e associação linear entre caracteres de Crotalaria spectabilis. Bragantia 76: 45-53.) recommended the evaluation from 241 to 12,107 plants of C. spectabilis, depending on the character to be measured.

Thumbnail

TABLE II
Sample size (number of pods) by resampling with replacement, to estimate the mean of eight characters measured in four species of crotalarias - C. juncea, C. spectabilis, C. breviflora and C. ochroleuca - in the season of 2014/15, for the amplitudes of the confidence interval of 95% (ACI _95% ) equal to 2%, 4%, ..., 20% of the mean.

For intermediate precision [amplitude of the confidence interval of 95% (ACI_95%) of 10% of the mean], the sample size ranged from 10 to 195 pods for C. juncea, from 10 to 65 pods for C. spectabilis, from 10 to 95 pods for C. breviflora and from 15 to 80 pods for C. ochroleuca, depending of the character (Table II). At this level of precision, the assessment of 20 pods is sufficient to estimate the mean of LP, WP and HP, regardless of the species considered. Whereas for MPWOS and MHS, 85 pods are necessary and, 195 pods for the determination of the characters MPWS, NSP and MHS, regardless of the species considered. Among the species, greater sample size is necessary to estimate the mean of C. juncea. As noted earlier, the characters MPWS, MPWOS, NSP, MSP and MHS showed greater variation, being higher the variation also in C. juncea (Table I), resulting in increased the sample size (Table II). For ACI_95% of 10% of the mean, Cargnelutti Filho et al. (2012) recommended the evaluation of 117 and 66 seeds, respectively, in jack bean and velvet bean. Leite et al. (2009LEITE MSO, PETERNELLI LA, BARBOSA MHP, CECON PR AND CRUZ CD. 2009. Sample size for full-sib family evaluation in sugarcane. Pesq Agropec Bras 44: 1562-1574.) verified that the sample size ranged in accordance with the genetic or phenotypic parameter and with the variable. For C. spectabilis, Toebe et al. (2017aTOEBE M, BANDEIRA CT, FORTES SKG, CARVALHO JO, TARTAGLIA FL, TAMBARA AL AND MELO PJ. 2017a. Dimensionamento amostral e associação linear entre caracteres de Crotalaria spectabilis. Bragantia 76: 45-53.) recommended from 10 to 484 plants and Teodoro et al. (2015TEODORO PE, SILVA JÚNIOR CA, RIBEIRO LP, SILVA FA, CORRÊA CCG, ZANUNCIO AS AND TORRES FE. 2015. Sample dimension for estimation of biomass and yield of sunn (Crotalaria juncea L.) and showy rattlebox (C. spectabilis Roth.). J Agron 14: 98-101.) recommended from 44 to 340 plants, depending of the character and the species of crotalaria, with semi-amplitude of 95% confidence interval of 5% of the mean.

Being adopted the lowest precision of this study [amplitude of the confidence interval of 95% (ACI_95%) of 20% of the mean], the sample size ranged from 10 to 55 pods for C. juncea, from 10 to 20 pods for C. spectabilis, from 10 to 25 pods for C. breviflora and from 10 to 20 pods for C. ochroleuca, depending on the character (Table II). C. juncea showed in general higher variability and, consequently, higher sample size compared to the other species (Tables I and II). In this and in other species of crotalaria, variability in the sample size in function of character was observed, being that ACI_95% in a simulated sample size was lower for the character length of pod (Figure 1a - shorter variability) in relation to ACI_95% of the mass of seeds per pod (Figure 1b - greater variability). Variability in sample size between characters or pairs of characters has been frequently reported in the literature, as it can be verified in sugar cane (Leite et al. 2009LEITE MSO, PETERNELLI LA, BARBOSA MHP, CECON PR AND CRUZ CD. 2009. Sample size for full-sib family evaluation in sugarcane. Pesq Agropec Bras 44: 1562-1574.), maize (Cargnelutti Filho et al. 2010, Toebe et al. 2014TOEBE M, CARGNELUTTI FILHO A, BURIN C, CASAROTTO G AND HAESBAERT FM. 2014. Tamanho de amostra para estimação da média e do coeficiente de variação em milho. Pesq Agropec Bras 49: 860-871. , 2015, 2017b), jack bean and velvet bean (Cargnelutti Filho et al. 2012), C. juncea (Teodoro et al. 2015TEODORO PE, SILVA JÚNIOR CA, RIBEIRO LP, SILVA FA, CORRÊA CCG, ZANUNCIO AS AND TORRES FE. 2015. Sample dimension for estimation of biomass and yield of sunn (Crotalaria juncea L.) and showy rattlebox (C. spectabilis Roth.). J Agron 14: 98-101.) and in C. spectabilis (Teodoro et al. 2015, Toebe et al. 2017a).

Figure 1
Percentile 2.5%, mean and percentile 97.5% of 10,000 estimates of: (a) the mean of the length of pods, in mm; (b) mean of the mass of seeds per pod, in g; (c) the coefficient of variation (CV) of the length of pods, in %, and; (d) the coefficient of variation of the mass of seeds per pod, in %, for the sample sizes n = 10, 20, ..., 1,000 pods of Crotalaria juncea.

For the estimation of the coefficient of variation (CV in %) in a higher level of precision [amplitude of the confidence interval of 95% (ACI_95%) of 2%], the sample size ranged between 55 to more than 1,000 pods, depending on the character and species (Table III). For intermediate precision [amplitude of the confidence interval of 95% (ACI_95%) of 10%], the sample size for the estimate of coefficient of variation ranged from 10 to 105 pods for C. juncea, from 10 to 55 pods for C. spectabilis, from 10 to 65 pods for C. breviflora and from 10 to 50 pods for C. ochroleuca, depending on the character. For the estimate of coefficient of variation, with ACI_95% of 5% in maize, Toebe et al. (2014TOEBE M, CARGNELUTTI FILHO A, BURIN C, CASAROTTO G AND HAESBAERT FM. 2014. Tamanho de amostra para estimação da média e do coeficiente de variação em milho. Pesq Agropec Bras 49: 860-871. ) verified the need of sample size from 20 to 725 ears, depending on the character, the year and hybrid to be evaluated.

Thumbnail

TABLE III
Sample size (number of pods) by resampling with replacement, to estimate the coefficient of variation of eight characters measured in four species of crotalarias - C. juncea, C. spectabilis, C. breviflora and C. ochroleuca - in the season of 2014/15, for the amplitudes of the confidence interval of 95% (ACI _95% ) equal to 2%, 4%, ..., 20%.

Species with lower variability, as for example C. spectabilis, need smaller sample size for estimating the coefficient of variation as compared to C. juncea (Table III). Still, characters that showed less variation, as for example, LP, WP and HP (Table I), needed smaller sample size to estimate the mean (Table II) and for the estimate of the coefficient of variation (Table III), holding a certain level of precision. In this sense, Kelley (2007KELLEY K. 2007. Sample size planning for the coefficient of variation from the accuracy in parameter estimation approach. Behav Res Methods 39: 755-766.) and Toebe et al. (2014TOEBE M, CARGNELUTTI FILHO A, BURIN C, CASAROTTO G AND HAESBAERT FM. 2014. Tamanho de amostra para estimação da média e do coeficiente de variação em milho. Pesq Agropec Bras 49: 860-871. ) also reported a need for greater sample size for estimating the coefficient of variation in variables with higher scores of coefficients of variation and vice-versa. The difference in variability of the sample size for estimating the coefficient of variation among characters of the same species can be found in Figure 1c, d, where the ACI_95% is lower for the length of pods in comparison to that seen for mass of seeds per pod in C. juncea. In these figures, it is also possible to check that the mean values of the coefficient of variation remains constant with increasing of the sample size, and there is a reduction of ACI_95%, i.e., the increase in sample size does not reduce the coefficient of variation, but reduces the variability of the estimate of the same, which means greater precision in the estimation of the coefficient of variation, as already observed by Toebe et al. (2014) in maize hybrids.

CONCLUSIONS

The sample size varies among species and characters, being necessary a larger sample size to estimate the mean in relation of the necessary for estimation of coefficient of variation. Based on this study, researchers will be able to size their experimental samples considering the species of crotalaria, variables and desired precision.

ACKNOWLEDGMENTS

We thank to the scholarship students and volunteers for their help in conducting experimental and data collection. To the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), to the Fundação de Amparo à Pesquisa do Estado do Rio Grande do Sul (FAPERGS), to the Programa de Educação Tutorial do Ministério da Educação and the Fundação Universidade Federal do Pampa (UNIPAMPA) by scholarships and financial support. To the company Piraí Sementes® for granting seeds to research purposes.

REFERENCES

BANIK S, KIBRIA BMG AND SHARMA D. 2012. Testing the population coefficient of variation. J Mod Appl Stat Methods 11: 325-335.
BHANDARI HR, TRIPATHI MK, CHAUDHARY B AND SARKAR SK. 2016. Sunnhemp breeding: Challenges and prospects. Indian J Agric Sci 86: 1391-1398.
BRAZ GBP, OLIVEIRA JRRS, CONSTANTIN J, RAIMONDI RT, RIBEIRO LM, GEMELLI A AND TAKANO HK. 2016. Plantas daninhas como hospedeiras alternativas para Pratylenchus brachyurus. Summa Phytopathol 42: 233-238.
CARGNELUTTI FILHO A, TOEBE M, BURIN C, FICK AL, ALVES BM AND FACCO G. 2012. Tamanho de amostra para a estimação da média do comprimento, diâmetro e massa de sementes de feijão de porco e mucuna cinza. Cienc Rural 42: 1541-1544.
CARGNELUTTI FILHO A, TOEBE M, BURIN C, SILVEIRA TR AND CASAROTTO G. 2010. Tamanho de amostra para estimação do coeficiente de correlação linear de Pearson entre caracteres de milho. Pesq Agropec Bras 45: 1363-1371.
CARGNELUTTI FILHO A, TOEBE M, FACCO G, SANTOS GO, ALVES BM AND BOLZAN A. 2013. Sample size for estimation of the plastochron in pigeonpea. Eur J Agron 48: 12-18.
CHAUDHARY B. 2016. Traditional cultivation of sunnhemp (Crotalaria juncea) in eastern India. Indian J Agric Sci 86: 369-372.
DEBERDT P, GOZÉ E, CORANSON-BEAUDU R, PERRIN B, FERNANDES P, LUCAS P AND RATNADASS A. 2015. Crotalaria spectabilis and Raphanus sativus as previous crops show promise for the control of bacterial wilt of tomato without reducing bacterial populations. J Phytopathol 163: 377-385.
DOANE DP AND SEWARD LE. 2011. Measuring Skewness: A Forgotten Statistic? J Stat Educ 19: 1-18.
FACCO G ET AL. 2017. Basic experimental unit and plot sizes with the method of maximum curvature of the coefficient of variation in sunn hemp. Afr J Agric Res 12: 415-423.
FERREIRA DF. 2009. Estatística básica, 2nd ed., Lavras: UFLA.
KELLEY K. 2007. Sample size planning for the coefficient of variation from the accuracy in parameter estimation approach. Behav Res Methods 39: 755-766.
KOUMANOV KS. 2017. Sample size determination in horticultural research: an empirical approach. Sci Hort 225: 416-421.
LEITE MSO, PETERNELLI LA, BARBOSA MHP, CECON PR AND CRUZ CD. 2009. Sample size for full-sib family evaluation in sugarcane. Pesq Agropec Bras 44: 1562-1574.
MACHADO ACZ, MOTTA LCC, SIQUEIRA KMS, FERRAZ LCCB AND INOMOTO MM. 2007. Host status of green manures for two isolates of Pratylenchus brachyurus in Brazil. Nematology 9: 799-805.
PANICHKITKOSOLKUL W. 2009. Improved confidence intervals for a coefficient of variation of a normal distribution. Thailand Statistician 7: 193-199.
R DEVELOPMENT CORE TEAM. 2017. R: A Language and Environment for Statistical Computing.
REIGADA C, GUIMARÃES KF AND PARRA JRP. 2016. Relative fitness of Helicoverpa armigera (Lepidoptera: Noctuidae) on seven host plants: a perspective for IPM in Brazil. J Insect Sci 16: 1-5.
SANTOS HG, ALMEIDA JA, OLIVEIRA JB, LUMBRERAS JF, ANJOS LHC, COELHO MR, JACOMINE PKT, CUNHA TJF AND OLIVEIRA VA. 2013. Sistema brasileiro de classificação de solos, 3rd ed., Brasília: EMBRAPA.
SILVA AR, HILÁRIO RF, RÊGO ER, NASCIMENTO NFF, DIAS CTS AND LIMA RP. 2015. A multivariate approach to determine sample size for morphological characterization of pepper fruits. Aust J Crop Sci 9: 1064-1068.
STORCK L, GARCIA DC, LOPES SJ AND ESTEFANEL V. 2016. Experimentação Vegetal, 3rd ed., Santa Maria: UFSM, 200 p.
TEODORO PE, SILVA JÚNIOR CA, RIBEIRO LP, SILVA FA, CORRÊA CCG, ZANUNCIO AS AND TORRES FE. 2015. Sample dimension for estimation of biomass and yield of sunn (Crotalaria juncea L.) and showy rattlebox (C. spectabilis Roth.). J Agron 14: 98-101.
TOEBE M, BANDEIRA CT, FORTES SKG, CARVALHO JO, TARTAGLIA FL, TAMBARA AL AND MELO PJ. 2017a. Dimensionamento amostral e associação linear entre caracteres de Crotalaria spectabilis. Bragantia 76: 45-53.
TOEBE M, CARGNELUTTI FILHO A, BURIN C, CASAROTTO G AND HAESBAERT FM. 2014. Tamanho de amostra para estimação da média e do coeficiente de variação em milho. Pesq Agropec Bras 49: 860-871.
TOEBE M, CARGNELUTTI FILHO A, LOPES SJ, BURIN C, SILVEIRA TR AND CASAROTTO G. 2015. Sample size in the estimation of correlation coefficients for corn hybrids in crops and accuracy levels. Bragantia 74: 16-24.
TOEBE M, CARGNELUTTI FILHO A, STORCK L AND LÚCIO AD. 2017b. Sample size for estimation of direct effects in path analysis of corn. Genet Mol Res 16: 1-23.
VARGAS TO, DINIZ ER, PACHECO ALV, SANTOS RHS AND URQUIAGA S. 2017. Green manure-15N absorbed by broccoli and zucchini in sequential cropping. Sci Hortic 214: 209-213.
WREGE MS, STEINMETZ S, REISSER JÚNIOR C AND ALMEIDA IR. 2011. Atlas climático da Região Sul do Brasil: Estados do Paraná, Santa Catarina e Rio Grande do Sul. Pelotas: Embrapa Clima Temperado; Embrapa Florestas.
WRIGHT DB AND HERRINGTON JA. 2011. Problematic standard errors and confidence intervals for skewness and kurtosis. Behav Res Methods 43: 8-17.

Publication Dates

Publication in this collection
16 Apr 2018
Date of issue
Apr-June 2018

History

Received
11 Oct 2017
Accepted
16 Nov 2017

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] BANIK S, KIBRIA BMG AND SHARMA D. 2012. Testing the population coefficient of variation. J Mod Appl Stat Methods 11: 325-335.

[2] BHANDARI HR, TRIPATHI MK, CHAUDHARY B AND SARKAR SK. 2016. Sunnhemp breeding: Challenges and prospects. Indian J Agric Sci 86: 1391-1398.

[3] BRAZ GBP, OLIVEIRA JRRS, CONSTANTIN J, RAIMONDI RT, RIBEIRO LM, GEMELLI A AND TAKANO HK. 2016. Plantas daninhas como hospedeiras alternativas para Pratylenchus brachyurus. Summa Phytopathol 42: 233-238.

[4] CARGNELUTTI FILHO A, TOEBE M, BURIN C, FICK AL, ALVES BM AND FACCO G. 2012. Tamanho de amostra para a estimação da média do comprimento, diâmetro e massa de sementes de feijão de porco e mucuna cinza. Cienc Rural 42: 1541-1544.

[5] CARGNELUTTI FILHO A, TOEBE M, BURIN C, SILVEIRA TR AND CASAROTTO G. 2010. Tamanho de amostra para estimação do coeficiente de correlação linear de Pearson entre caracteres de milho. Pesq Agropec Bras 45: 1363-1371.

[6] CARGNELUTTI FILHO A, TOEBE M, FACCO G, SANTOS GO, ALVES BM AND BOLZAN A. 2013. Sample size for estimation of the plastochron in pigeonpea. Eur J Agron 48: 12-18.

[7] CHAUDHARY B. 2016. Traditional cultivation of sunnhemp (Crotalaria juncea) in eastern India. Indian J Agric Sci 86: 369-372.

[8] DEBERDT P, GOZÉ E, CORANSON-BEAUDU R, PERRIN B, FERNANDES P, LUCAS P AND RATNADASS A. 2015. Crotalaria spectabilis and Raphanus sativus as previous crops show promise for the control of bacterial wilt of tomato without reducing bacterial populations. J Phytopathol 163: 377-385.

[9] DOANE DP AND SEWARD LE. 2011. Measuring Skewness: A Forgotten Statistic? J Stat Educ 19: 1-18.

[10] FACCO G ET AL. 2017. Basic experimental unit and plot sizes with the method of maximum curvature of the coefficient of variation in sunn hemp. Afr J Agric Res 12: 415-423.

[11] FERREIRA DF. 2009. Estatística básica, 2nd ed., Lavras: UFLA.

[12] KELLEY K. 2007. Sample size planning for the coefficient of variation from the accuracy in parameter estimation approach. Behav Res Methods 39: 755-766.

[13] KOUMANOV KS. 2017. Sample size determination in horticultural research: an empirical approach. Sci Hort 225: 416-421.

[14] LEITE MSO, PETERNELLI LA, BARBOSA MHP, CECON PR AND CRUZ CD. 2009. Sample size for full-sib family evaluation in sugarcane. Pesq Agropec Bras 44: 1562-1574.

[15] MACHADO ACZ, MOTTA LCC, SIQUEIRA KMS, FERRAZ LCCB AND INOMOTO MM. 2007. Host status of green manures for two isolates of Pratylenchus brachyurus in Brazil. Nematology 9: 799-805.

[16] PANICHKITKOSOLKUL W. 2009. Improved confidence intervals for a coefficient of variation of a normal distribution. Thailand Statistician 7: 193-199.

[17] R DEVELOPMENT CORE TEAM. 2017. R: A Language and Environment for Statistical Computing.

[18] REIGADA C, GUIMARÃES KF AND PARRA JRP. 2016. Relative fitness of Helicoverpa armigera (Lepidoptera: Noctuidae) on seven host plants: a perspective for IPM in Brazil. J Insect Sci 16: 1-5.

[19] SANTOS HG, ALMEIDA JA, OLIVEIRA JB, LUMBRERAS JF, ANJOS LHC, COELHO MR, JACOMINE PKT, CUNHA TJF AND OLIVEIRA VA. 2013. Sistema brasileiro de classificação de solos, 3rd ed., Brasília: EMBRAPA.

[20] SILVA AR, HILÁRIO RF, RÊGO ER, NASCIMENTO NFF, DIAS CTS AND LIMA RP. 2015. A multivariate approach to determine sample size for morphological characterization of pepper fruits. Aust J Crop Sci 9: 1064-1068.

[21] STORCK L, GARCIA DC, LOPES SJ AND ESTEFANEL V. 2016. Experimentação Vegetal, 3rd ed., Santa Maria: UFSM, 200 p.

[22] TEODORO PE, SILVA JÚNIOR CA, RIBEIRO LP, SILVA FA, CORRÊA CCG, ZANUNCIO AS AND TORRES FE. 2015. Sample dimension for estimation of biomass and yield of sunn (Crotalaria juncea L.) and showy rattlebox (C. spectabilis Roth.). J Agron 14: 98-101.

[23] TOEBE M, BANDEIRA CT, FORTES SKG, CARVALHO JO, TARTAGLIA FL, TAMBARA AL AND MELO PJ. 2017a. Dimensionamento amostral e associação linear entre caracteres de Crotalaria spectabilis. Bragantia 76: 45-53.

[24] TOEBE M, CARGNELUTTI FILHO A, BURIN C, CASAROTTO G AND HAESBAERT FM. 2014. Tamanho de amostra para estimação da média e do coeficiente de variação em milho. Pesq Agropec Bras 49: 860-871.

[25] TOEBE M, CARGNELUTTI FILHO A, LOPES SJ, BURIN C, SILVEIRA TR AND CASAROTTO G. 2015. Sample size in the estimation of correlation coefficients for corn hybrids in crops and accuracy levels. Bragantia 74: 16-24.

[26] TOEBE M, CARGNELUTTI FILHO A, STORCK L AND LÚCIO AD. 2017b. Sample size for estimation of direct effects in path analysis of corn. Genet Mol Res 16: 1-23.

[27] VARGAS TO, DINIZ ER, PACHECO ALV, SANTOS RHS AND URQUIAGA S. 2017. Green manure-15N absorbed by broccoli and zucchini in sequential cropping. Sci Hortic 214: 209-213.

[28] WREGE MS, STEINMETZ S, REISSER JÚNIOR C AND ALMEIDA IR. 2011. Atlas climático da Região Sul do Brasil: Estados do Paraná, Santa Catarina e Rio Grande do Sul. Pelotas: Embrapa Clima Temperado; Embrapa Florestas.

[29] WRIGHT DB AND HERRINGTON JA. 2011. Problematic standard errors and confidence intervals for skewness and kurtosis. Behav Res Methods 43: 8-17.

	Characters measured (measurement units)⁽¹⁾
Statistic	MPWS (g)	MPWOS (g)	LP (mm)	WP (mm)	HP (mm)	NSP (un.)	MSP (g)	MHS (g)
Crotalaria juncea
Minimum	0.15	0.09	22.59	8.18	5.50	1.00	0.05	1.70
Mean	0.50	0.17	29.52	10.93	7.70	6.94	0.33	4.81
Median	0.49	0.16	29.47	10.88	7.69	7.00	0.32	4.89
Maximum	0.89	0.26	36.57	14.27	9.72	13.00	0.68	8.16
Variance	0.02	0.00	5.39	1.05	0.51	4.75	0.01	1.26
SD	0.14	0.03	2.32	1.02	0.71	2.18	0.12	1.12
CV(%)	27.40	16.75	7.86	9.37	9.24	31.39	36.31	23.29
Asymmetry⁽²⁾	0.15*	0.24*	0.10^ns	0.35*	0.09^ns	0.20*	0.18*	-0.15*
Kurtosis⁽³⁾	-0.29^ns	-0.26^ns	-0.11^ns	0.11^ns	-0.05^ns	-0.27^ns	-0.32*	-0.29^ns
P-value	0.83	0.15	0.92	0.31	0.67	0.00	0.36	0.31
Crotalaria spectabilis
Minimum	0.31	0.20	35.32	11.94	7.79	5.00	0.08	1.28
Mean	0.68	0.36	41.74	15.47	9.83	17.91	0.32	1.78
Median	0.69	0.36	41.82	15.48	9.85	18.00	0.32	1.78
Maximum	0.98	0.52	49.55	18.19	11.82	28.00	0.50	2.38
Variance	0.01	0.00	5.23	0.99	0.36	12.17	0.00	0.02
SD	0.11	0.05	2.29	0.99	0.60	3.49	0.07	0.16
CV(%)	15.98	14.93	5.48	6.43	6.09	19.48	20.51	8.83
Asymmetry⁽²⁾	-0.34*	-0.07^ns	-0.11^ns	-0.15^ns	-0.01^ns	-0.70*	-0.51*	-0.03^ns
Kurtosis⁽³⁾	0.24^ns	-0.12^ns	-0.04^ns	-0.09^ns	0.39*	0.91*	0.55*	0.86*
P-value	0.32	0.91	0.39	0.65	0.48	0.00	0.13	0.14
Crotalaria breviflora
Minimum	0.27	0.17	32.92	8.53	6.44	5.00	0.08	1.11
Mean	0.61	0.27	39.55	10.45	8.08	17.45	0.33	1.91
Median	0.61	0.27	39.53	10.47	8.10	18.00	0.34	1.93
Maximum	0.89	0.40	45.91	12.18	9.49	25.00	0.54	2.70
Variance	0.01	0.00	4.57	0.39	0.25	13.89	0.01	0.06
SD	0.11	0.04	2.14	0.63	0.50	3.73	0.08	0.25
CV(%)	17.64	15.14	5.40	5.99	6.16	21.37	24.11	13.16
Asymmetry⁽²⁾	-0.21*	0.12^ns	-0.08^ns	-0.12^ns	-0.11^ns	-0.76*	-0.39*	-0.26*
Kurtosis⁽³⁾	-0.05^ns	-0.26^ns	-0.18^ns	-0.18^ns	0.04^ns	0.45*	0.00^ns	0.23^ns
P-value	0.27	0.76	0.92	0.66	0.43	0.00	0.04	0.12
Crotalaria ochroleuca
Minimum	0.45	0.25	41.06	11.52	8.00	26.00	0.18	0.43
Mean	1.10	0.52	56.28	16.84	11.49	81.16	0.57	0.71
Median	1.10	0.51	56.52	16.82	11.49	83.00	0.58	0.71
Maximum	1.71	0.86	72.62	21.85	15.09	115.00	0.97	1.01
Variance	0.05	0.01	25.03	3.05	1.47	215.09	0.02	0.01
SD	0.21	0.11	5.00	1.75	1.21	14.67	0.13	0.10
CV(%)	19.53	21.17	8.89	10.37	10.53	18.07	22.13	14.43
Asymmetry⁽²⁾	0.04^ns	0.29*	-0.24*	-0.08^ns	0.09^ns	-0.77*	-0.13^ns	0.00^ns
Kurtosis⁽³⁾	-0.01^ns	-0.18^ns	0.19^ns	0.05^ns	-0.16^ns	0.89*	0.22^ns	-0.15^ns
P-value	0.36	0.05	0.25	0.36	0.86	0.00	0.25	1.00

Characters measured ⁽¹⁾
ACI_95%	MPWS	MPWOS	LP	WP	HP	NSP	MSP	MHS
Sample size (number of pods) for mean estimation in Crotalaria juncea
2%	>1,000	>1,000	235	320	325	>1,000	>1,000	>1,000
4%	720	270	60	90	85	950	>1,000	505
6%	320	120	30	40	35	425	555	235
8%	185	70	20	25	25	220	320	130
10%	115	45	10	15	15	155	195	85
12%	85	30	10	10	10	110	140	60
14%	65	25	10	10	10	80	105	45
16%	45	20	10	10	10	65	80	35
18%	35	15	10	10	10	50	65	30
20%	30	15	10	10	10	40	55	25
Sample size (number of pods) for mean estimation in Crotalaria spectabilis
2%	970	840	120	165	145	>1,000	>1,000	300
4%	250	215	30	45	35	370	400	75
6%	110	95	15	20	20	170	185	35
8%	60	55	10	10	10	95	105	20
10%	40	35	10	10	10	60	65	15
12%	30	25	10	10	10	45	45	10
14%	20	20	10	10	10	30	35	10
16%	20	15	10	10	10	25	30	10
18%	15	15	10	10	10	20	20	10
20%	10	10	10	10	10	15	20	10
Sample size (number of pods) for mean estimation in Crotalaria breviflora
2%	>1,000	870	115	140	150	>1,000	>1,000	670
4%	290	220	30	35	40	445	550	165
6%	135	100	15	20	20	195	245	75
8%	75	60	10	10	10	115	145	45
10%	50	40	10	10	10	70	95	30
12%	35	25	10	10	10	50	65	20
14%	25	20	10	10	10	35	50	15
16%	20	15	10	10	10	30	40	15
18%	15	15	10	10	10	25	30	10
20%	15	10	10	10	10	20	25	10
Sample size (number of pods) for mean estimation in Crotalaria ochroleuca
2%	>1,000	>1,000	305	415	425	>1,000	>1,000	795
4%	365	430	80	105	105	325	475	200
6%	165	195	35	50	50	140	210	90
8%	95	110	20	30	30	85	120	55
10%	60	75	15	20	20	50	80	35
12%	45	50	10	15	15	35	55	25
14%	30	40	10	10	10	30	40	20
16%	25	30	10	10	10	20	30	15
18%	20	25	10	10	10	20	25	10
20%	15	20	10	10	10	15	20	10

Characters measured ⁽¹⁾
AIC_95%	MPWS	MPWOS	LP	WP	HP	NSP	MSP	MHS
Sample size (number of pods) for the coefficient of variation estimation in Crotalaria juncea
2%	>1,000	460	115	165	165	>1,000	>1,000	>1,000
4%	330	115	30	45	45	435	605	270
6%	150	55	15	20	20	200	275	120
8%	85	30	10	15	15	115	155	70
10%	55	20	10	10	10	75	105	45
12%	40	15	10	10	10	55	75	35
14%	30	15	10	10	10	40	55	25
16%	25	10	10	10	10	30	40	20
18%	20	10	10	10	10	25	35	15
20%	15	10	10	10	10	20	30	15
Sample size (number of pods) for the coefficient of variation estimation in Crotalaria spectabilis
2%	625	430	60	80	90	>1,000	>1,000	220
4%	160	110	20	25	25	320	315	55
6%	75	50	10	10	10	145	140	25
8%	40	30	10	10	10	85	80	15
10%	30	20	10	10	10	55	50	10
12%	20	15	10	10	10	40	35	10
14%	15	10	10	10	10	30	30	10
16%	10	10	10	10	10	25	20	10
18%	10	10	10	10	10	20	20	10
20%	10	10	10	10	10	15	15	10
Sample size (number of pods) for the coefficient of variation estimation in Crotalaria breviflora
2%	665	385	55	70	75	>1,000	>1,000	405
4%	165	100	15	20	20	350	360	100
6%	75	45	10	10	10	160	165	45
8%	45	30	10	10	10	90	95	30
10%	30	20	10	10	10	60	65	20
12%	20	15	10	10	10	45	45	15
14%	15	10	10	10	10	30	35	10
16%	15	10	10	10	10	25	25	10
18%	10	10	10	10	10	20	20	10
20%	10	10	10	10	10	15	15	10
Sample size (number of pods) for the coefficient of variation estimation in Crotalaria ochroleuca
2%	780	745	180	220	200	>1,000	>1,000	390
4%	195	185	50	60	50	285	305	95
6%	90	85	25	30	25	130	135	45
8%	50	50	15	15	15	75	75	30
10%	35	35	10	10	10	45	50	20
12%	25	25	10	10	10	35	35	15
14%	20	20	10	10	10	25	25	10
16%	15	15	10	10	10	20	20	10
18%	15	15	10	10	10	15	20	10
20%	10	10	10	10	10	15	15	10