Cost Estimates Through the Project Lifecycle

Purpose and Context

Strategic planning estimates support high-level investment decisions before significant resources are committed to project development. These estimates help determine:

• Which potential projects warrant further investigation
• Approximate funding requirements for long-term capital programs
• Comparative costs of strategic alternatives
• Order-of-magnitude benefits versus costs

Estimating Approach

Strategic planning estimates are typically developed using global estimating methods:

• Composite rates: High-level unit rates applied to key project parameters (e.g., $/lane-km for road projects, $/station for rail)
• Historical rates: Costs from similar completed projects adjusted for scope differences, location, and escalation
• Benchmark data: Industry-standard cost ranges for project types and scales
• Parametric models: Statistical relationships between project characteristics and costs

These methods are appropriate given the limited design information available at this stage. They provide sufficient accuracy for strategic decisions without requiring detailed quantity take-offs or design development.

Work Breakdown Structure Level

Strategic planning estimates are typically structured at:

• WBS Level 2 (major cost categories) as the primary breakdown
• Selected Level 3 items for supporting detail where significant cost impacts are anticipated

This level of detail is sufficient for strategic comparison and programming without excessive effort on projects that may not proceed beyond planning stages.

Expected Accuracy and Contingency

Due to limited design information and high uncertainty:

• Expected accuracy range: typically -30% to +50% or broader
• Contingency allowances: 30-50% of base estimate to reflect uncertainty
• Estimates presented as ranges rather than point values where appropriate

Concept phase estimates are used for high-stakes decision-making, including government budget approvals and public commitments. Consequently, they require significantly greater rigour than strategic planning estimates.

Project Proposal / SASR Estimates

The first formal estimate in the Concept Phase supports the Strategic Assessment of Service Requirement (SASR) and Project Proposal:

• Purpose: Secure approval to proceed with business case development
• Scope definition: Preliminary scope based on identified service needs
• Method: Refined global estimates or preliminary unit rate estimates
• Accuracy: Typically -20% to +30%
• WBS detail: Levels 1-2 with selected Level 3 items

Options Analysis / Preliminary Evaluation Estimates

As the business case develops, multiple options are evaluated and compared:

• Purpose: Enable objective comparison of alternative solutions
• Requirement: Consistent estimating methodology across all options for fair comparison
• Method: Combination of unit rates and first principles for differentiating elements
• Accuracy: Sufficient to distinguish meaningful cost differences between options
• Documentation: Clear identification of cost drivers and differentiators between options

Comparative accuracy is more important than absolute accuracy at this stage. Estimates must use consistent assumptions and methods so that cost differences between options are meaningful.

Business Case Estimates - The Critical Milestone

The Business Case estimate is arguably the most important estimate in the entire project lifecycle. It establishes the funding envelope, informs ministerial and cabinet decisions, and becomes the baseline against which project performance is measured.

Business Case Estimate Requirements

• Estimating method: First principles and unit rates (global estimates not sufficient)
• WBS structure: Levels 1-3 mandatory, selected Level 4 for major elements
• Risk assessment: Comprehensive risk workshop and quantified risk register
• Contingency: Probabilistic analysis (Monte Carlo) to determine P50 and P90
• Validation: Independent peer review mandatory
• Concurrence review: Required for projects exceeding $25 million
• Accuracy expectation: P50 typically -10% to +15%, P90 provides high confidence buffer

Business Case Estimate Components

A comprehensive business case estimate includes:

• Base estimate: Most likely cost of all scope elements
• Risk allowance: Quantified cost of identified risks
• Contingency: Allowance for uncertainty and unknown risks
• Escalation: Cost increases over time to project completion
• Outturn cost: Total funding requirement in year-of-expenditure dollars

Why P90 Matters

The P90 estimate provides 90% confidence that the project can be delivered within budget. This high confidence level is appropriate for government funding decisions because:

• Budget overruns have political and reputational consequences
• Government funding is typically fixed rather than contingent
• Projects compete for limited capital, so budget reliability is critical
• Public accountability demands projects be delivered within approved funding

However, P90 should not be viewed as a target or as "free money" to spend. It represents the prudent funding level given uncertainty, and should reduce as risks are retired and design matures.

Stage 1 Design (S1D) Estimates

S1D estimates are developed once preliminary design (typically 15-30% design completion) is available:

Purpose and Function

• Budget verification: Confirm the project remains within the business case funding envelope
• Value engineering: Identify opportunities for cost optimization while meeting project objectives
• Scope refinement: Support decisions on scope inclusions and priorities
• Risk update: Reassess risks based on design development

Estimating Characteristics

• Method: Predominantly first principles with detailed quantity take-offs where design permits
• WBS detail: Levels 1-3 comprehensive, expanding Level 4 detail
• Accuracy target: -10% to +15% at P50
• Contingency: Reducing from business case levels as design matures

S1D estimates often reveal scope elements that were underestimated or not fully considered during business case development. This is a critical reality check before significant design investment continues.

Stage 2 Design (S2D) Estimates

S2D estimates accompany detailed design (typically 90-100% complete) immediately prior to tender release:

Purpose and Function

• Tender expectation: Establish the expected market price for contract award
• Budget confirmation: Final verification before market engagement
• Tender evaluation: Provide the baseline for assessing tender submissions
• Procurement strategy: Inform decisions on packaging and contract strategy

Estimating Characteristics

• Method: Detailed first principles with comprehensive quantity take-offs from final design
• WBS detail: Levels 1-4 comprehensive, selected Level 5 for complex elements
• Accuracy target: -5% to +10% at P50
• Contractor perspective: Estimating from the contractor's perspective, including overheads, profit, and risk pricing
• Market conditions: Explicit consideration of current market pricing, availability, and risk appetite

S2D estimates should closely approximate tender prices if design is complete and market conditions are well understood. Significant divergence suggests either estimating issues or market factors requiring investigation.

Estimate for Comparison with Tenders (EFCT)

The EFCT is prepared specifically for tender evaluation and may be a refined version of the S2D estimate:

Key Requirements

• Based on the exact scope and specifications in tender documentation
• Incorporates latest market intelligence from pre-tender market soundings
• Structured to align with tender evaluation criteria and schedule of rates
• Provides the reference point for tender evaluation and negotiation
• Must remain confidential to avoid influencing tender prices

The EFCT gives the client confidence that tender prices are fair and reasonable. Tenders significantly above or below the EFCT warrant investigation before award.

Agreed Project Delivery Value (APDV)

Once tenders are evaluated and a preferred contractor selected, the APDV is established:

Definition and Purpose

The APDV is the negotiated contract sum plus client-side costs (e.g., project management, independent certification, remaining design). It becomes the formal project budget for delivery.

APDV Components

• Contract sum: The awarded construction contract value
• Client costs: Project management, supervision, testing, commissioning
• Authority contingency: Client-held contingency for variations and risks
• Escalation: Remaining escalation to project completion

The APDV is compared to the business case budget to verify the project remains affordable. If APDV exceeds available funding, either additional funding must be secured or scope reduced before contract award.

Cost Forecasting and Periodic Updates

Throughout construction, regular cost forecasts are prepared to track expenditure against budget and predict final outturn:

Forecast Components

• Committed costs: Contract sum and approved variations
• Anticipated costs: Pending variations and known changes
• Contingency draw-down: Tracking utilization of contingency allowances
• Forecast final outturn: Predicted total cost at project completion

Forecasting Frequency

Cost forecasts are typically updated:

• Monthly as part of project reporting and dashboard updates
• Quarterly for executive and governance reporting
• On-demand when significant changes or risks emerge

Effective forecasting enables proactive cost management, identifies emerging issues early, and supports informed decision-making on scope trade-offs and risk mitigation.

Contract Variation Estimates

When changes to contracted scope occur, variation estimates must be prepared:

Variation Estimating Requirements

• Detailed scope definition: Clear description of what has changed from baseline contract
• Independent assessment: Client-side estimate before contractor pricing where practical
• Schedule of rates: Application of contract rates where applicable
• Market rates: Current market rates for new work outside contract scope
• Time impacts: Assessment of program delay and associated costs
• Documentation: Audit trail supporting variation approval

Variation management is a critical cost control function. Having independent variation estimates ensures the client can negotiate fair pricing and identify unreasonable contractor claims.

Change Management and Contingency Draw-Down

Authority-held contingency is drawn down during implementation for approved scope changes and realized risks:

Contingency Management Principles

• Contingency is not "extra budget" but an allowance for uncertainty that should reduce as uncertainty resolves
• Draw-down requires formal approval based on demonstrable need
• Remaining contingency is forecast against remaining risks and anticipated changes
• Depletion of contingency triggers escalation and management response

Final Cost Documentation

Comprehensive documentation of final project costs provides critical data for future estimating:

Required Documentation

• Actual costs: Final contract sum including all variations
• Client costs: All project management, design, and ancillary costs
• Total project cost: All-in cost for complete project delivery
• Cost breakdown: Actual costs by WBS element for benchmarking
• Unit rates: Derived actual unit rates for SmartCost database

Post Implementation Review (PIR)

The PIR is a formal review conducted after project completion to assess performance and capture lessons learned:

Cost Estimating Components of PIR

• Budget performance: Comparison of final costs to business case, S1D, S2D, and APDV estimates
• Variance analysis: Understanding why estimates varied from actual costs
• Risk realization: Which risks materialized and at what cost impact
• Scope changes: Documenting approved changes and their cost effects
• Estimating accuracy: Assessment of estimate quality and areas for improvement

Contribution to SmartCost Database

Final project costs are submitted to Queensland's SmartCost database to inform future estimates:

SmartCost Submission Requirements

• Structured cost data by PCEM WBS elements
• Project characteristics (location, scale, delivery method, etc.)
• Unit rates for key elements
• Lessons learned and estimating notes
• Context information to support future adjustment and application

This data becomes the historical foundation for Step 6 of the PCEM estimating process for future projects. The quality and completeness of SmartCost submissions directly impacts the accuracy of future Queensland infrastructure estimates.

Lessons Learned for Future Estimates

Beyond numerical cost data, finalisation should capture qualitative lessons:

• What estimating assumptions proved incorrect and why
• Which risks were underestimated or overlooked
• What scope elements were consistently under or over estimated
• How market conditions or contractor behavior differed from expectations
• What estimating methods or data sources proved most reliable

Organizations that systematically capture and apply these lessons progressively improve their estimating capability and reduce the variability between estimates and outcomes.