Calculating Weight Needed for Scuba Diving

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Scuba Diving Weight Calculator

Ensure optimal buoyancy for your dives by accurately calculating the weight needed. This calculator helps you find the right ballast for a safe and enjoyable underwater experience.

Scuba Dive Weight Calculation

Enter your total weight, including swimwear. (e.g., 75 kg)
No Suit (Rash Guard) 3mm Wetsuit 5mm Wetsuit 7mm Wetsuit Drysuit Select the type and thickness of your exposure suit.
Standard Jacket BCD Back Inflate BCD Wing/Harness System Choose the type of Buoyancy Control Device you use.
Aluminum 80 cu ft Steel 200 cu ft Steel 100 cu ft Select the tank you will be using for the dive.
Freshwater Saltwater Saltwater is denser than freshwater, requiring less weight.
Add any extra weight you typically carry (e.g., for cameras, specialized gear).

Your Recommended Dive Weight

Base Weight: kg
Suit Buoyancy Compensation: kg
BCD Buoyancy Compensation: kg
Tank Buoyancy: kg

Key Assumptions:

Diver Weight: kg
Suit Type:
BCD Type:
Tank Type:
Water Salinity:
Additional Weight: kg
Results copied to clipboard!
Typical Buoyancy Factors (kg)
Item Freshwater Adjustment Saltwater Adjustment
Standard Jacket BCD +3.0 kg +2.0 kg
Back Inflate BCD +3.5 kg +2.5 kg
Wing/Harness System +2.0 kg +1.0 kg
3mm Wetsuit +1.5 kg +1.0 kg
5mm Wetsuit +3.0 kg +2.0 kg
7mm Wetsuit +4.5 kg +3.5 kg
Drysuit (with undergarments) +6.0 kg +5.0 kg
Aluminum 80 cu ft Tank -2.5 kg (negatively buoyant) -1.0 kg (slightly buoyant when empty)
Steel 100 cu ft Tank -4.0 kg (negatively buoyant) -3.0 kg (negatively buoyant)
Steel 200 cu ft Tank -8.0 kg (very negatively buoyant) -7.0 kg (very negatively buoyant)
Chart showing the contribution of different factors to required weight.

What is Scuba Diving Weight Calculation?

Scuba diving weight calculation is the process of determining the correct amount of ballast weight a diver needs to wear to achieve neutral buoyancy underwater. Neutral buoyancy is crucial for safe, efficient, and enjoyable scuba diving. It allows the diver to hover effortlessly at any depth without sinking or floating uncontrollably. Proper weight distribution ensures the diver can maintain control, conserve energy, and avoid disturbing the marine environment. It's a fundamental skill for all scuba divers, from beginners to seasoned professionals.

This calculation is essential for anyone participating in scuba diving activities. It's not just for recreational divers; technical divers, commercial divers, and even underwater photographers rely on precise buoyancy control. Without the right weight, divers can struggle to descend, ascend safely, or maintain their desired depth, leading to discomfort, increased air consumption, and potential safety hazards. Misconceptions often arise about simply adding "a lot of weight," but the reality is a finely tuned balance based on multiple physical factors.

Common misconceptions include believing that more weight is always better for staying down, or that a drysuit eliminates the need for weight. In reality, over-weighting is a significant safety risk, leading to difficulty ascending, excessive air consumption, and potential decompression sickness. Conversely, under-weighting makes descending and maintaining depth challenging. A drysuit, while adding significant buoyancy when inflated, still requires careful weight management, especially when deflated or in specific water conditions. The goal is always neutral buoyancy, not just sinking.

Scuba Diving Weight Calculation Formula and Mathematical Explanation

The core principle behind calculating scuba diving weight is to offset the positive buoyancy generated by the diver's body, equipment, and BCD, while accounting for the negative buoyancy of certain gear like steel tanks. The formula aims to find the total weight (W_total) needed to counteract all buoyant forces.

A simplified, practical approach can be represented as:

Total Weight Needed (kg) = (Diver's Weight + Equipment Weight) – (BCD Buoyancy + Suit Buoyancy + Tank Buoyancy) + Additional Weight

Let's break down the components:

  1. Diver's Weight (W_diver): This is the primary factor – the diver's mass in air.
  2. Suit Buoyancy (B_suit): Wetsuits and drysuits trap gas (air or water) which creates buoyancy. Thicker suits and drysuits trap more gas, thus creating more buoyancy that needs to be overcome. This is typically calculated as a weight offset based on suit type and thickness.
  3. BCD Buoyancy (B_bcd): The BCD, especially when partially or fully inflated, contains a volume of air that provides lift. Different BCD designs have varying capacities.
  4. Tank Buoyancy (B_tank): The buoyancy of a scuba tank depends heavily on its material (aluminum vs. steel) and its fill level. Aluminum tanks are nearly neutral or slightly positively buoyant when empty, while steel tanks are significantly negatively buoyant. For calculations, we often consider a partially filled or nearly empty tank's buoyancy contribution.
  5. Water Salinity: Saltwater is denser than freshwater. This means it provides more buoyant force for the same volume. Therefore, a diver needs slightly less weight in saltwater than in freshwater to achieve neutral buoyancy. This acts as a multiplier or adjustment factor.
  6. Additional Weight (W_add): This accounts for personal preferences, specific dive conditions (e.g., strong currents), or extra gear like underwater cameras.

The calculator uses empirical data and typical values for buoyancy compensation for different gear types and water conditions.

Variable Explanations and Typical Ranges:

Scuba Diving Weight Calculation Variables
Variable Meaning Unit Typical Range/Values
Diver's Weight (W_diver) The total mass of the diver in air. kg 40 – 150+ kg
Suit Thickness Thickness of wetsuit or description of drysuit. mm / Type 0mm, 3mm, 5mm, 7mm, Drysuit
BCD Type Type of Buoyancy Control Device. Type Jacket, Back Inflate, Wing
Tank Type Material and volume of the scuba tank. Type (cu ft) Aluminum 80, Steel 100, Steel 200
Water Salinity Density of the water the dive will occur in. Type Freshwater, Saltwater
Additional Weight (W_add) User-defined extra weight for specific needs. kg 0 – 5+ kg
Base Weight Needed Initial calculation based on diver weight and water type. kg Calculated
Suit Buoyancy Compensation Weight offset required to counteract suit's buoyancy. kg Calculated
BCD Buoyancy Compensation Weight offset required to counteract BCD's buoyancy. kg Calculated
Tank Buoyancy Adjustment Adjustment for the tank's inherent buoyancy (often negative). kg Calculated
Total Weight Needed Final recommended ballast weight. kg Calculated

Practical Examples (Real-World Use Cases)

Understanding how different factors influence the required weight is best illustrated with examples:

Example 1: Cold Water Diving with Drysuit

Scenario: A diver weighing 80 kg is preparing for a dive in cold saltwater using a 7mm wetsuit and a steel 100 cu ft tank. They are using a standard jacket BCD.

Inputs:

  • Diver's Weight: 80 kg
  • Exposure Suit Thickness: 7mm Wetsuit
  • BCD Type: Standard Jacket BCD
  • Tank Type: Steel 100 cu ft
  • Water Salinity: Saltwater
  • Additional Weight: 0 kg

Calculation Process:

  • Base Weight (Saltwater): Approximately 80 kg * 1.02 (saltwater density factor) ≈ 81.6 kg (This is a simplified initial estimate; the calculator uses specific offsets)
  • Suit Buoyancy (7mm wetsuit in saltwater): -2.0 kg (from table)
  • BCD Buoyancy (Standard Jacket in saltwater): -2.0 kg (from table)
  • Tank Buoyancy (Steel 100 cu ft): -3.0 kg (from table)
  • Total Weight Needed ≈ 81.6 kg – 2.0 kg – 2.0 kg – 3.0 kg + 0 kg = 76.6 kg

Calculator Result (Example): The calculator might output a recommended weight of approximately 7.0 kg (this is the *added* weight, not total diver weight). The specific calculation logic in the tool refines these offsets.

Interpretation: The diver needs around 7.0 kg of lead weight. The substantial buoyancy from the 7mm wetsuit and the steel tank requires significant offsetting weight, even in saltwater. This diver might consider a weight integrated BCD or a weight belt.

Example 2: Warm Water Diving with Minimal Exposure

Scenario: A diver weighing 65 kg is going for a recreational dive in tropical saltwater, wearing only a rash guard (no wetsuit) and using an aluminum 80 cu ft tank with a back inflate BCD.

Inputs:

  • Diver's Weight: 65 kg
  • Exposure Suit Thickness: No Suit (Rash Guard)
  • BCD Type: Back Inflate BCD
  • Tank Type: Aluminum 80 cu ft
  • Water Salinity: Saltwater
  • Additional Weight: 1 kg (for a small camera)

Calculation Process:

  • Base Weight (Saltwater): Approximately 65 kg * 1.02 ≈ 66.3 kg
  • Suit Buoyancy (Rash guard): ~0 kg
  • BCD Buoyancy (Back inflate in saltwater): -2.5 kg (from table)
  • Tank Buoyancy (Aluminum 80 cu ft): -1.0 kg (from table)
  • Total Weight Needed ≈ 66.3 kg + 0 kg – 2.5 kg – 1.0 kg + 1.0 kg = 63.8 kg

Calculator Result (Example): The calculator might suggest around 3.0 kg of added weight.

Interpretation: In this scenario, the diver needs significantly less weight, around 3.0 kg. The primary sources of negative buoyancy are the aluminum tank and potentially the BCD. The lack of a thick exposure suit means less counteracting weight is needed.

How to Use This Scuba Diving Weight Calculator

Using the Scuba Diving Weight Calculator is straightforward and designed to provide quick, actionable results. Follow these steps:

  1. Enter Diver's Weight: Input your total weight in kilograms (kg), including the swimwear or thin layer you'll wear during the dive.
  2. Select Exposure Suit: Choose the appropriate thickness of your wetsuit or select 'Drysuit' if applicable. If you're only wearing a rash guard, choose 'No Suit'.
  3. Choose BCD Type: Select the type of Buoyancy Control Device you use (Standard Jacket, Back Inflate, or Wing/Harness).
  4. Specify Tank Type: Indicate the material and common size of the tank you'll be using (e.g., Aluminum 80 cu ft, Steel 100 cu ft).
  5. Set Water Salinity: Choose whether you'll be diving in Freshwater or Saltwater.
  6. Add Extra Weight (Optional): If you typically carry additional gear like cameras or tools that affect your buoyancy, enter their approximate weight contribution in kg.
  7. Calculate: Click the "Calculate Weight" button.

Reading the Results:

  • Primary Result: This is the total recommended ballast weight (in kg) you should wear, usually distributed between a weight belt and/or integrated weights in your BCD.
  • Intermediate Values: These show the calculated contribution of your base weight, suit buoyancy, BCD buoyancy, and tank buoyancy. This helps understand where the weight requirements are coming from.
  • Key Assumptions: A summary of the inputs you provided, confirming the parameters used in the calculation.
  • Formula Explanation: A brief note on the general principle behind the calculation.

Decision-Making Guidance: The calculated weight is a starting point. Always perform a buoyancy check at the surface before your first dive. Gradually add or remove weight until you can float effortlessly with a normal breath in, and sink slowly when you exhale completely. Adjustments may be needed based on personal preference, dive conditions, and specific equipment variations. Never rely solely on a calculator; hands-on testing is essential for safety.

Key Factors That Affect Scuba Diving Weight Results

Several variables significantly influence the amount of weight you need for scuba diving. Understanding these factors is key to achieving optimal buoyancy:

  1. Diver's Body Composition: Muscle is denser than fat, meaning a more muscular diver may require slightly less weight than a diver of the same mass but with a higher body fat percentage. While the calculator uses total weight, this is a subtle underlying factor.
  2. Exposure Suit Thickness and Material: This is one of the most significant factors. Thicker wetsuits and drysuits trap more gas (air or gas mixture), increasing buoyancy. A 7mm wetsuit requires considerably more weight than a 3mm suit or a rash guard. Drysuits, especially when inflated, create substantial buoyancy.
  3. Type of BCD: Different BCD designs have varying internal volumes and shapes. Back inflate BCDs and wing systems may offer different buoyancy characteristics compared to traditional jacket BCDs, influencing the amount of weight needed to counteract them.
  4. Scuba Tank Material and Fill Level: Steel tanks are denser (more negatively buoyant) than aluminum tanks. An empty steel tank provides significant weight underwater, whereas an aluminum tank can become nearly neutral or even slightly positively buoyant when empty. The fill level also matters; a full tank is slightly more buoyant than an empty one due to the compressed air.
  5. Water Density (Salinity and Temperature): Saltwater is denser than freshwater, providing more buoyant force. Therefore, you need less weight in saltwater. Colder water often means denser divers and denser suits, potentially requiring minor adjustments, though salinity is the primary water density factor accounted for.
  6. Personal Buoyancy Control Technique: A diver's ability to manage their breathing and BCD inflation/deflation plays a role. While the calculation provides a baseline, experienced divers might fine-tune their weight based on their refined buoyancy control skills.
  7. Additional Gear: Heavy items like large underwater camera setups, video lights, sampling equipment, or even tools for commercial diving can add to the overall buoyancy or require specific weighting strategies.
  8. Dive Profile and Depth: While less critical for basic weight calculation, as you descend, the air in your exposure suit and BCD compresses, reducing buoyancy. This is managed through BCD inflation, but initial weighting must account for the suit's buoyancy at surface pressure.

Frequently Asked Questions (FAQ)

  • Q1: How much weight do I need for a scuba dive?

    A1: The amount of weight needed varies greatly depending on your body weight, exposure suit, BCD, tank type, and water salinity. Use the calculator above for a personalized estimate, but always perform a buoyancy check at the surface.

  • Q2: Should I use a weight belt or integrated weights?

    A2: Both have pros and cons. Weight belts are traditional and allow easy ditching in emergencies. Integrated weights are convenient, distribute weight evenly, and are less likely to slip. Modern BCDs often come with integrated weight systems.

  • Q3: Does my BCD's buoyancy affect how much weight I need?

    A3: Yes. Your BCD, especially when inflated, provides lift. A larger or more buoyant BCD requires you to wear more weight to achieve neutral buoyancy.

  • Q4: Why do I need less weight in saltwater?

    A4: Saltwater is denser than freshwater. Denser fluids provide greater buoyant force. To counteract this increased buoyant force and achieve neutral buoyancy, you need to wear less weight in saltwater.

  • Q5: What happens if I wear too much weight?

    A5: Wearing too much weight (over-weighting) is dangerous. It makes it difficult to ascend, increases air consumption, can lead to involuntary descents, and poses a risk of decompression sickness if you ascend too quickly.

  • Q6: What happens if I wear too little weight?

    A6: Wearing too little weight (under-weighting) makes it difficult or impossible to descend. You may struggle to stay down, use more air trying to manage buoyancy, and find it hard to maintain position during a dive.

  • Q7: How do I perform a buoyancy check at the surface?

    A7: With your BCD fully inflated and a near-empty tank, put on your calculated weight. Enter the water, fully inflate your BCD, and take a normal breath. You should float passively. Then, exhale completely; you should begin a slow, controlled descent. Adjust weight as needed.

  • Q8: Should I account for my camera gear in my weight calculation?

    A8: Yes, if your camera setup is significantly buoyant or negatively buoyant, it can affect your overall buoyancy. Add or subtract weight based on the gear's properties and your experience. Using the 'Additional Weight' field is appropriate for this.

  • Q9: Do I need to recalculate my weight every dive?

    A9: Not usually. Once you determine the correct weight for your standard setup and typical diving conditions (e.g., wetsuit thickness, saltwater), you likely won't need to change it unless your equipment, suit, or typical diving environment changes. However, always confirm buoyancy at the start of a dive day or after significant equipment changes.

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var diverWeightInput = document.getElementById('diverWeight'); var suitThicknessSelect = document.getElementById('suitThickness'); var bcdTypeSelect = document.getElementById('bcdType'); var tankTypeSelect = document.getElementById('tankType'); var waterSalinitySelect = document.getElementById('waterSalinity'); var additionalWeightInput = document.getElementById('additionalWeight'); var diverWeightError = document.getElementById('diverWeightError'); var suitThicknessError = document.getElementById('suitThicknessError'); var bcdTypeError = document.getElementById('bcdTypeError'); var tankTypeError = document.getElementById('tankTypeError'); var waterSalinityError = document.getElementById('waterSalinityError'); var additionalWeightError = document.getElementById('additionalWeightError'); var resultContainer = document.getElementById('resultContainer'); var primaryResult = document.getElementById('primaryResult'); var baseWeightResult = document.getElementById('baseWeightResult'); var suitBuoyancyResult = document.getElementById('suitBuoyancyResult'); var bcdBuoyancyResult = document.getElementById('bcdBuoyancyResult'); var tankBuoyancyResult = document.getElementById('tankBuoyancyResult'); var assumptionDiverWeight = document.getElementById('assumptionDiverWeight'); var assumptionSuitType = document.getElementById('assumptionSuitType'); var assumptionBcdType = document.getElementById('assumptionBcdType'); var assumptionTankType = document.getElementById('assumptionTankType'); var assumptionWaterSalinity = document.getElementById('assumptionWaterSalinity'); var assumptionAdditionalWeight = document.getElementById('assumptionAdditionalWeight'); var formulaExplanation = document.getElementById('formulaExplanation'); var copyFeedback = document.getElementById('copyFeedback'); var chart; var chartContext; var buoyancyFactors = { freshwater: { bcd: { standard: 3.0, back: 3.5, wing: 2.0 }, suit: { 0: 0, // No suit 3: 1.5, // 3mm 5: 3.0, // 5mm 7: 4.5, // 7mm dry: 6.0 // Drysuit }, tank: { aluminum80: -2.5, steel100: -4.0, steel200: -8.0 } }, saltwater: { bcd: { standard: 2.0, back: 2.5, wing: 1.0 }, suit: { 0: 0, // No suit 3: 1.0, // 3mm 5: 2.0, // 5mm 7: 3.5, // 7mm dry: 5.0 // Drysuit }, tank: { aluminum80: -1.0, steel100: -3.0, steel200: -7.0 } } }; function validateInput(input, errorElement, min, max) { var value = parseFloat(input.value); var isValid = true; errorElement.style.display = 'none'; if (isNaN(value)) { errorElement.innerText = 'Please enter a valid number.'; errorElement.style.display = 'block'; isValid = false; } else if (input.id === 'diverWeight' && value <= 0) { errorElement.innerText = 'Diver weight must be positive.'; errorElement.style.display = 'block'; isValid = false; } else if (input.id === 'additionalWeight' && value < 0) { errorElement.innerText = 'Additional weight cannot be negative.'; errorElement.style.display = 'block'; isValid = false; } else if (min !== undefined && max !== undefined && (value max)) { errorElement.innerText = 'Value out of range.'; errorElement.style.display = 'block'; isValid = false; } return isValid; } function calculateWeight() { copyFeedback.style.display = 'none'; // Hide copy feedback on new calculation var isValid = true; if (!validateInput(diverWeightInput, diverWeightError)) isValid = false; if (!validateInput(additionalWeightInput, additionalWeightError)) isValid = false; if (!isValid) { resultContainer.style.display = 'none'; return; } var diverWeight = parseFloat(diverWeightInput.value); var suitThickness = suitThicknessSelect.value; var bcdType = bcdTypeSelect.value; var tankType = tankTypeSelect.value; var waterSalinity = waterSalinitySelect.value; var additionalWeight = parseFloat(additionalWeightInput.value); var currentWaterFactors = buoyancyFactors[waterSalinity]; if (!currentWaterFactors) { console.error("Invalid water salinity selected."); resultContainer.style.display = 'none'; return; } var bcdBuoyancyOffset = currentWaterFactors.bcd[bcdType] || 0; var suitBuoyancyOffset = currentWaterFactors.suit[suitThickness] || 0; var tankBuoyancyOffset = currentWaterFactors.tank[tankType] || 0; // Simple base weight estimation – more weight needed in denser (salt) water conceptually // However, the offsets already account for salinity, so we can simplify here // The primary driver of needing *more* weight is overcoming buoyancy, // which is directly handled by the negative offsets from BCD, suit, and tank. // Diver weight is the baseline mass to be neutralized. var baseWeight = diverWeight; // Start with diver's mass var calculatedTotalWeightNeeded = baseWeight – bcdBuoyancyOffset – suitBuoyancyOffset – tankBuoyancyOffset + additionalWeight; // Ensure the final result is not excessively low or negative due to offsets // A diver always needs *some* weight unless they are naturally very dense // and using only minimal gear. A safe minimum is usually considered ~2-4kg // for most setups. var finalWeight = Math.max(calculatedTotalWeightNeeded, 2.0); // Ensure a reasonable minimum weight // Update intermediate results baseWeightResult.innerText = baseWeight.toFixed(1); suitBuoyancyResult.innerText = suitBuoyancyOffset.toFixed(1); bcdBuoyancyResult.innerText = bcdBuoyancyOffset.toFixed(1); tankBuoyancyResult.innerText = tankBuoyancyOffset.toFixed(1); // Update assumptions display assumptionDiverWeight.innerText = diverWeight.toFixed(1); assumptionSuitType.innerText = suitThicknessSelect.options[suitThicknessSelect.selectedIndex].text; assumptionBcdType.innerText = bcdTypeSelect.options[bcdTypeSelect.selectedIndex].text; assumptionTankType.innerText = tankTypeSelect.options[tankTypeSelect.selectedIndex].text; assumptionWaterSalinity.innerText = waterSalinitySelect.options[waterSalinitySelect.selectedIndex].text; assumptionAdditionalWeight.innerText = additionalWeight.toFixed(1); // Update primary result primaryResult.innerText = finalWeight.toFixed(1) + " kg"; // Update formula explanation formulaExplanation.innerHTML = "Formula Used: Recommended Weight = (Diver's Weight) – (BCD Buoyancy) – (Suit Buoyancy) – (Tank Buoyancy) + (Additional Weight). Values are adjusted for water salinity."; resultContainer.style.display = 'block'; // Update Chart updateChart(baseWeight, suitBuoyancyOffset, bcdBuoyancyOffset, tankBuoyancyOffset, additionalWeight, finalWeight); } function resetCalculator() { diverWeightInput.value = 75; // Sensible default suitThicknessSelect.value = '5'; // Default to 5mm wetsuit bcdTypeSelect.value = 'standard'; tankTypeSelect.value = 'aluminum80'; waterSalinitySelect.value = 'salt'; additionalWeightInput.value = 0; // Clear errors diverWeightError.innerText = "; diverWeightError.style.display = 'none'; suitThicknessError.innerText = "; suitThicknessError.style.display = 'none'; bcdTypeError.innerText = "; bcdTypeError.style.display = 'none'; tankTypeError.innerText = "; tankTypeError.style.display = 'none'; waterSalinityError.innerText = "; waterSalinityError.style.display = 'none'; additionalWeightError.innerText = "; additionalWeightError.style.display = 'none'; resultContainer.style.display = 'none'; if (chart) { chart.destroy(); chart = null; } } function copyResults() { var resultsText = "Scuba Diving Weight Calculation Results:\n\n"; resultsText += "Recommended Weight: " + primaryResult.innerText + "\n"; resultsText += "—————————\n"; resultsText += "Base Weight: " + baseWeightResult.innerText + " kg\n"; resultsText += "Suit Buoyancy Compensation: " + suitBuoyancyResult.innerText + " kg\n"; resultsText += "BCD Buoyancy Compensation: " + bcdBuoyancyResult.innerText + " kg\n"; resultsText += "Tank Buoyancy Adjustment: " + tankBuoyancyResult.innerText + " kg\n"; resultsText += "—————————\n"; resultsText += "Assumptions:\n"; resultsText += "Diver Weight: " + assumptionDiverWeight.innerText + "\n"; resultsText += "Suit Type: " + assumptionSuitType.innerText + "\n"; resultsText += "BCD Type: " + assumptionBcdType.innerText + "\n"; resultsText += "Tank Type: " + assumptionTankType.innerText + "\n"; resultsText += "Water Salinity: " + assumptionWaterSalinity.innerText + "\n"; resultsText += "Additional Weight: " + assumptionAdditionalWeight.innerText + "\n"; var textArea = document.createElement("textarea"); textArea.value = resultsText; document.body.appendChild(textArea); textArea.select(); document.execCommand("copy"); textArea.remove(); copyFeedback.style.display = 'block'; setTimeout(function() { copyFeedback.style.display = 'none'; }, 3000); } function initializeChart() { chartContext = document.getElementById('weightDistributionChart').getContext('2d'); chart = new Chart(chartContext, { type: 'bar', data: { labels: ['Base Weight', 'Suit Buoyancy', 'BCD Buoyancy', 'Tank Buoyancy', 'Additional Weight', 'Total Needed'], datasets: [{ label: 'Weight Contribution (kg)', data: [0, 0, 0, 0, 0, 0], backgroundColor: [ 'rgba(0, 74, 153, 0.6)', // Base Weight (Blue) 'rgba(40, 167, 69, 0.6)', // Suit Buoyancy (Green) – Negative effect, represented positively for chart ease 'rgba(23, 162, 184, 0.6)', // BCD Buoyancy (Teal) – Negative effect 'rgba(108, 117, 125, 0.6)', // Tank Buoyancy (Gray) – Negative effect 'rgba(255, 193, 7, 0.6)', // Additional Weight (Yellow) 'rgba(255, 87, 34, 0.8)' // Total Needed (Orange) ], borderColor: [ 'rgba(0, 74, 153, 1)', 'rgba(40, 167, 69, 1)', 'rgba(23, 162, 184, 1)', 'rgba(108, 117, 125, 1)', 'rgba(255, 193, 7, 1)', 'rgba(255, 87, 34, 1)' ], borderWidth: 1 }] }, options: { responsive: true, maintainAspectRatio: true, scales: { y: { beginAtZero: true, title: { display: true, text: 'Weight (kg)' } } }, plugins: { legend: { display: false // Legend is clear from labels }, title: { display: true, text: 'Breakdown of Dive Weight Calculation' } } } }); } function updateChart(baseWeight, suitBuoyancyOffset, bcdBuoyancyOffset, tankBuoyancyOffset, additionalWeight, finalWeight) { if (!chart) { initializeChart(); } if (chart && chartContext) { // Note: Suit, BCD, and Tank buoyancy offsets are negative values representing lift. // For the bar chart, we display their magnitude (positive value) to show contribution. // The 'Total Needed' is the final result. chart.data.datasets[0].data = [ baseWeight, Math.abs(suitBuoyancyOffset), // Displaying magnitude Math.abs(bcdBuoyancyOffset), // Displaying magnitude Math.abs(tankBuoyancyOffset), // Displaying magnitude additionalWeight, finalWeight ]; chart.update(); } } // Initial calculation on load document.addEventListener('DOMContentLoaded', function() { resetCalculator(); // Set sensible defaults calculateWeight(); // Perform initial calculation initializeChart(); // Initialize the chart });

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