Fixed Quantity Inventory Model: Definition, Calculation & Practical Examples

Calculate reorder point as: ROP = (Average Daily Demand × Lead Time in Days) + Safety Stock. For international shipments, lead time includes production, inland transport, customs clearance, and ocean/air freight. Safety stock compensates for demand variability and lead time uncertainty, typically calculated using service level targets and standard deviation of lead time demand.

Yes, but with modifications. For perishable items, holding costs must include spoilage and obsolescence rates, which significantly increase the cost parameter. This typically reduces the optimal order quantity compared to non-perishable goods. Many companies use a modified approach combining EOQ principles with maximum shelf-life constraints to prevent waste while optimizing costs.

Include all transaction-specific costs: purchase order processing, freight forwarding fees, customs brokerage charges, import duties and taxes, inspection fees, bank charges for letters of credit, and inland transportation to your warehouse. For containerized cargo, also factor in container deposits, demurrage risks, and port handling charges. These costs typically range from 2-8% of cargo value.

Review quarterly for stable products, monthly for seasonal items, and immediately when significant changes occur in demand patterns, supplier lead times, freight rates, or holding costs. Major events like new warehouse locations, supplier changes, or market disruptions warrant immediate recalculation. Automated inventory management systems can trigger recalculations based on variance thresholds.

The basic EOQ model doesn't, but the Price Break EOQ variant does. Compare the total cost (ordering + holding + purchase) at each discount threshold. Sometimes ordering above the optimal EOQ makes economic sense if the price reduction exceeds the increased holding cost. Calculate total annual cost for each option to identify the true optimum.

Safety stock depends on your desired service level and demand/lead time variability. Use the formula: Safety Stock = Z-score × √(Lead Time × Demand Variance). For 95% service level, Z = 1.65; for 99%, Z = 2.33. International shipments typically require higher safety stock (15-25% of average demand during lead time) due to greater uncertainty compared to domestic supply chains.

Container economics often override pure EOQ calculations. A 20-foot container holds approximately 28 cubic meters, while a 40-foot holds 58. If your calculated EOQ fills 75% of a container, consider adjusting to a full container load to maximize freight efficiency. The incremental holding cost of 25% more inventory often costs less than inefficient container utilization.

Yes, but it requires careful safety stock management. For products with coefficient of variation (standard deviation ÷ mean demand) above 0.5, consider calculating separate EOQs for peak and off-peak seasons. Alternatively, implement dynamic safety stock that adjusts based on recent demand patterns. Some companies use hybrid approaches combining Fixed Quantity for stable SKUs with other methods for variable ones.

Industry standards range from 15-35% of item value annually. Include: capital cost (8-15%), warehouse space (3-7%), insurance (1-3%), taxes (1-3%), obsolescence (2-5%), and shrinkage (1-3%). For imported goods, add currency hedging costs if applicable. High-tech products typically use 25-35% due to rapid obsolescence, while commodity items may use 15-20%.

Lead time variability directly increases required safety stock. Calculate standard deviation of historical lead times and incorporate into your reorder point formula: ROP = (Average Demand × Average Lead Time) + (Z-score × Standard Deviation of Lead Time Demand). For international shipments with 30-day average lead time and 7-day standard deviation, this significantly impacts optimal inventory levels compared to domestic sources with consistent 3-5 day lead times.

No. The ordering cost component differs dramatically—air freight typically costs 5-10 times more than ocean freight, which increases the optimal EOQ for ocean shipments. Many companies maintain two separate systems: smaller EOQs with higher frequency for air-shipped items (urgent restocks) and larger EOQs for ocean-shipped items (planned replenishment). Calculate separate EOQs for each mode based on their respective ordering and transit costs.