Variance Estimation Sample Clauses

The Variance Estimation clause defines the method and process for calculating the variability or spread of data within a given dataset or project. Typically, this clause outlines the statistical techniques or formulas to be used, such as standard deviation or other relevant measures, and may specify the data sources or timeframes applicable for the estimation. Its core practical function is to ensure consistency and transparency in how variance is measured, which helps stakeholders assess risk, monitor performance, and make informed decisions based on reliable data analysis.
Variance Estimation. To obtain estimates of variability (such as the standard error of sample estimates or corresponding confidence intervals) for estimates based on MEPS survey data, one needs to take into account the complex sample design of MEPS. Various approaches can be used to develop such estimates of variance including use of the ▇▇▇▇▇▇ series or various replication methodologies. Replicate weights have not been developed for the MEPS 1996 data. Variables needed to implement a ▇▇▇▇▇▇ series estimation approach are described in the paragraph below. Using a ▇▇▇▇▇▇ Series approach, variance estimation strata and the variance estimation PSUs within these strata must be specified. The corresponding variables on the MEPS full year utilization database are VARSTR96 and VARPSU96, respectively. Specifying a “with replacement” design in a computer software package such as SUDAAN (▇▇▇▇, 1996) should provide standard errors appropriate for assessing the variability of MEPS survey estimates. It should be noted that the number of degrees of freedom associated with estimates of variability indicated by such a package may not appropriately reflect the actual number available. For MEPS sample estimates for characteristics generally distributed throughout the country (and thus the sample PSUs), there are over 100 degrees of freedom associated with the corresponding estimates of variance. The following illustrates these concepts using two examples from Section 4.2. Using a ▇▇▇▇▇▇ series approach, specifying VARSTR96 and VARPSU96 as the variance estimation strata and PSUs (within these strata) respectively and specifying a “with replacement” design in the computer software package SUDAAN will yield an estimate of standard error of $136 for the estimated mean of out-of-pocket payment.
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Variance Estimation. MEPS has a complex sample design. To obtain estimates of variability (such as the standard error of sample estimates or corresponding confidence intervals) for MEPS estimates, analysts need to take into account the complex sample design of MEPS for both person-level and family- level analyses. Several methodologies have been developed for estimating standard errors for surveys with a complex sample design, including the ▇▇▇▇▇▇-series linearization method, balanced repeated replication, and jackknife replication. Various software packages provide analysts with the capability of implementing these methodologies. Replicate weights have not been developed for the MEPS data. Instead, the variables needed to calculate appropriate standard errors based on the ▇▇▇▇▇▇-series linearization method are included on this point-in-time file as well as all other MEPS public use files. Software packages that permit the use of the ▇▇▇▇▇▇-series linearization method include SUDAAN, Stata, SAS (version 8.2 and higher), and SPSS (version 12.0 and higher). For complete information on the capabilities of each package, analysts should refer to the corresponding software user documentation. Using the ▇▇▇▇▇▇-series linearization method, variance estimation strata and the variance estimation PSUs within these strata must be specified. The variables VARSTR and VARPSU on this MEPS data file serve to identify the sampling strata and primary sampling units required by the variance estimation programs. Specifying a “with replacement” design in one of the previously mentioned computer software packages will provide estimated standard errors appropriate for assessing the variability of MEPS survey estimates. It should be noted that the number of degrees of freedom associated with estimates of variability indicated by such a package may not appropriately reflect the number available. For variables of interest distributed throughout the country (and thus the MEPS sample PSUs), one can generally expect to have at least 100 degrees of freedom associated with the estimated standard errors for national estimates based on this MEPS database. Initially, MEPS variance strata and PSUs were developed independently from year to year, and the last two characters of the strata and PSU variable names denoted the rounds. However, beginning with the 2002 Point-in-Time PUF, the variance strata and PSUs were developed to be compatible with all future PUF until the NHIS design changed. As discussed, this chan...
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Variance Estimation. (▇▇▇▇▇▇, VARSTR)
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Variance Estimation. (VARSTR00, VARPSU00) Examples 2 and 3 from Section 4.2
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Variance Estimation. To obtain estimates of variability (such as the standard error of sample estimates or corresponding confidence intervals) for estimates based on MEPS survey data, the complex sample design of MEPS for both person and family-level analyses must be taken into account. Various approaches can be used to develop such estimates of variance including use of the ▇▇▇▇▇▇ series or replication methodologies. Replicate weights have not been developed for the MEPS 1998 data. Using a ▇▇▇▇▇▇ Series approach, variance estimation strata and the variance estimation PSUs within these strata must be specified. The corresponding variables on the 1998 MEPS full year utilization database are VARSTR98 and VARPSU98, respectively. Specifying a “with replacement” design in a computer software package, such as SUDAAN, should provide standard errors appropriate for assessing the variability of MEPS survey estimates. It should be noted that the number of degrees of freedom associated with estimates of variability indicated by such a package may not appropriately reflect the actual number available. For MEPS sample estimates for characteristics generally distributed throughout the country (and thus the sample PSUs), there are over 100 degrees of freedom for the 1998 full year data associated with the corresponding estimates of variance.
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Variance Estimation. (▇▇▇▇▇▇, VARSTR) 1. When pooling any year from 2002 or later, one can use the variance strata numbering as is. 2. When pooling any year from 1996 to 2001 with any year from 2002 or later, use the H36 file. 3. A new H36 file will be constructed in the future to allow pooling of 2007 and later years with 1996 to 2006.
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Variance Estimation. To obtain estimates of variability (such as the standard error of sample estimates or corresponding confidence intervals) for estimates based on MEPS survey data, one needs to take into account the complex sample design of MEPS. Various approaches can be used to develop such estimates of variance including use of the ▇▇▇▇▇▇ series or various replication methodologies. Replicate weights have not been developed for the MEPS 1999 data. Variables needed to implement a ▇▇▇▇▇▇ series estimation approach are provided in the file and are described in the paragraph below. Using a ▇▇▇▇▇▇ Series approach, variance estimation strata and the variance estimation PSUs within these strata must be specified. The corresponding variables on the MEPS full year utilization database are VARSTR99 and VARPSU99, respectively. Specifying a “with replacement” design in a computer software package such as SUDAAN (Shah, 1996) should provide standard errors appropriate for assessing the variability of MEPS survey estimates. It should be noted that the number of degrees of freedom associated with estimates of variability indicated by such a package may not appropriately reflect the actual number available. For MEPS sample estimates for characteristics generally distributed throughout the country (and thus the sample PSUs), there are over 100 degrees of freedom associated with the corresponding estimates of variance.
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Variance Estimation. Variance provides a means of assessing and reporting the precision of a point estimate, playing a critical role in the interval estimation, hypothesis testing, and power calculation. In this section, asymptotic variance formulas for different IRA statistics in the review are summarized, which allows approximate variance estimations for those IRA measures based ▇▇▇▇▇▇-corrected IRA statistics with ICC interpretations ▇▇▇▇▇▇▇ and ▇▇▇▇▇▇▇▇’s 𝑟11 Equal when 𝑛10 = 𝑛01 Mak’s 𝜌˜ ▇▇▇▇▇’▇ κ Equal when 𝑛10 = 𝑛01 ▇▇▇▇▇’▇ π Equal when 𝑛11= 𝑛00 Equal when 𝑛11 = 𝑛00 and 𝑛10 = 𝑛01 ▇▇▇▇▇▇▇▇▇▇▇▇’s α ▇▇▇ ▇▇▇▇’▇ 𝐼2 r Gwet’s 𝐴𝐶1 on the observed data from Table 1. e|κ ▇▇▇▇▇▇, ▇▇▇▇▇, and ▇▇▇▇▇▇▇ [47] proposed a variance estimator for ▇▇▇▇▇’▇ κ under the nonnull case of IRA, and Gwet [12] rewrote the variance formula under the two-rater case for better comparability with the estimated variances of several other IRA statistics. The estimated variance of κ is given as Vˆar(κ) = npˆ (1 − pˆ ) − 4(1 − κ) pˆ ωˆ + pˆ (1 − ωˆ) − κpˆ N (1 − pˆe|κ )2 11 00 + 4(1 − κ)2 pˆ ωˆ2 + 1 pˆ (2pˆ + pˆ )2 + 1 pˆ 01 01 10 00 (2pˆ + pˆ )2 + pˆ (1 − ωˆ)2 ,, where ωˆ = pˆ11 + pˆ10/2 + pˆ01/2. The performance of this large-sample variance of κ have been evaluated via Monte Carlo simulations in ▇▇▇▇▇▇▇▇▇ and ▇▇▇▇▇▇ [48] and Fleiss and ▇▇▇▇▇▇▇▇▇ [49]. ˆ For ▇▇▇▇▇▇▇ et al.’s S and the several equivalent IRA measures mentioned in the review, since the asymptotic variance estimator of percent agreement could be obtained as Var(pˆa) = pˆa(1 − pˆa)/N based on the binomial properties, we can get the variance estimator for S = 2pˆa − 1 as ˆ Var(S) = N pˆa(1 − pˆa). For ▇▇▇▇▇’▇ π, Gwet [12] proposed a nonparametric variance estimator with linearization techniques to remedy the formula proposed by ▇▇▇▇▇▇ [50], which was under the hypothesis of no agreement and was not valid for building up confidence intervals. Under our scenario of interest, the variance formula of π can be written as 1 N (1 − pˆe|π )2 11 Vˆar(π) = npˆ (1 − pˆ ) − 4(1 − π) pˆ 00 e|π ωˆ + pˆ (1 − ωˆ) − pˆ pˆ 11 ˆ + ( 4 10 01 00 + 4(1 − π)2 pˆ ω2 pˆ + pˆ ) + pˆ (1 − ωˆ)2 − pˆ2 ,. e|π Regarding Gwet’s AC1, Gwet [12] utilized a linear approximation that included all terms with a stochastic order of magnitude up to N−1/2 to derive a consistent variance estimator. The variance formula of AC1 is given by Vˆar(AC ) = npˆ (1 − pˆ ) − 4(1 − AC ) pˆ (1 − ωˆ) + pˆ ωˆ − pˆ pˆ N (1 − pˆe|AC1 )2 1 11 1 11 ˆ) + ( 4 + 4(1 − AC )2 pˆ
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Variance Estimation. The MEPS is based on a complex sample design. To obtain estimates of variability (such as the standard error of sample estimates or corresponding confidence intervals) for MEPS estimates, analysts need to take into account the complex sample design of MEPS for both person-level and family-level analyses. Several methodologies have been developed for estimating standard errors for surveys with a complex sample design, including the ▇▇▇▇▇▇-series linearization method, balanced repeated replication, and jackknife replication. Various software packages provide analysts with the capability of implementing these methodologies. MEPS analysts most commonly use the ▇▇▇▇▇▇ Series approach. However, an option is also provided to apply the BRR approach when needed to develop variances for more complex estimators.
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Related to Variance Estimation

  • Cost Estimate The cost estimate shall set out the estimated costs for the proposed Change Order in such a way that a fair evaluation can be made. It shall include a breakdown for labor, materials, equipment and markups for overhead and profit, unless TxDOT agrees otherwise. If the work is to be performed by Subcontractors and if the work is sufficiently defined to obtain Subcontractor quotes, DB Contractor shall obtain quotes (with breakdowns showing cost of labor, materials, equipment and markups for overhead and profit) on the Subcontractor’s stationery and shall include such quotes as back-up for DB Contractor’s estimate. No markup shall be allowed in excess of the amounts allowed under Section 10.6. DB Contractor shall identify all conditions with respect to prices or other aspects of the cost estimate, such as pricing contingent on firm orders being made by a certain date or the occurrence or non-occurrence of an event.

  • Pre-Estimate The parties agree that if Market Quotation applies an amount recoverable under this Section 6(e) is a reasonable pre-estimate of loss and not a penalty. Such amount is payable for the loss of bargain and the loss of protection against future risks and except as otherwise provided in this Agreement neither party will be entitled to recover any additional damages as a consequence of such losses.

  • Cost Estimates If this Agreement pertains to the design of a public works project, CONSULTANT shall submit estimates of probable construction costs at each phase of design submittal. If the total estimated construction cost at any submittal exceeds the CITY’s stated construction budget by ten percent (10%) or more, CONSULTANT shall make recommendations to CITY for aligning the Project design with the budget, incorporate CITY approved recommendations, and revise the design to meet the Project budget, at no additional cost to CITY.

  • Estimate The Engineer shall independently develop and report quantities necessary to construct the contract in standard State bid format at the specified milestones and Final PS&E submittals. The Engineer shall prepare each construction cost estimates using Estimator or any approved method. The estimate shall be provided at each milestone submittal or in DCIS format at the 95% and Final PS&E submittals per State’s District requirement.

  • Statement of Estimated Direct Expenses In addition, Landlord shall give Tenant a yearly expense estimate statement (the “Estimate Statement”) which shall set forth Landlord’s reasonable estimate (the “Estimate”) of what the total amount of Direct Expenses for the then-current Expense Year shall be and the estimated Tenant’s Share of Direct Expenses (the “Estimated Direct Expenses”). The failure of Landlord to timely furnish the Estimate Statement for any Expense Year shall not preclude Landlord from enforcing its rights to collect any Estimated Direct Expenses under this Article 4, nor shall Landlord be prohibited from revising any Estimate Statement or Estimated Direct Expenses theretofore delivered to the extent necessary. Thereafter, Tenant shall pay, with its next installment of Base Rent due that is at least thirty (30) days thereafter, a fraction of the Estimated Direct Expenses for the then-current Expense Year (reduced by any amounts paid pursuant to the last sentence of this Section 4.4.2). Such fraction shall have as its numerator the number of months which have elapsed in such current Expense Year, including the month of such payment, and twelve (12) as its denominator. Until a new Estimate Statement is furnished (which Landlord shall have the right to deliver to Tenant at any time), Tenant shall pay monthly, with the monthly Base Rent installments, an amount equal to one-twelfth (1/12) of the total Estimated Direct Expenses set forth in the previous Estimate Statement delivered by Landlord to Tenant.