name

morphological-analysis-triz

description

Use when need systematic innovation through comprehensive solution space exploration, resolving technical contradictions (speed vs precision, strength vs weight, cost vs quality), generating novel product configurations, exploring all feasible design alternatives before prototyping, finding inventive solutions to engineering problems, identifying patent opportunities through parameter combinations, or when user mentions morphological analysis, Zwicky box, TRIZ, inventive principles, technical contradictions, systematic innovation, or design space exploration.

Morphological Analysis & TRIZ

Purpose
When to Use
What Is It
Workflow
Common Patterns
Guardrails
Quick Reference

Purpose

Systematically explore solution spaces through morphological analysis (parameter-option matrices) and resolve technical contradictions using TRIZ inventive principles to generate novel, non-obvious solutions.

When to Use

Systematic Exploration:

Explore all feasible configurations before committing
Generate comprehensive set of design alternatives
Create product line variations across parameters
Document complete solution space

Innovation & Invention:

Find novel, non-obvious solutions
Generate patentable innovations
Discover synergies between features
Break out of conventional thinking

Resolving Contradictions:

Improve one parameter without worsening another
Solve "impossible" trade-offs (faster AND cheaper)
Apply proven inventive principles
Resolve conflicts between requirements

Engineering & Design:

Design new products/systems from scratch
Optimize existing designs systematically
Configure complex systems with many parameters

What Is It

Two complementary methods:

Morphological Analysis: Decompose problem into parameters, identify options for each, systematically combine to explore solution space.

Parameters: Power (3 options) × Size (4 options) × Material (3 options) = 36 configurations

TRIZ: Resolve contradictions using 40 inventive principles. Example: "Improve speed → worsens precision" solved by Principle #1 (Segmentation): fast rough pass + slow precision pass.

Workflow

Copy this checklist:

Morphological Analysis & TRIZ Progress:
- [ ] Step 1: Define problem and objectives
- [ ] Step 2: Choose method (MA, TRIZ, or both)
- [ ] Step 3: Build morphological box (if MA)
- [ ] Step 4: Identify contradictions (if TRIZ)
- [ ] Step 5: Apply TRIZ principles
- [ ] Step 6: Evaluate and select solutions

Step 1: Define problem and objectives

Clarify problem statement, key objectives, constraints (cost, size, time, materials), and success criteria.

Step 2: Choose method

Morphological Analysis: 3-7 clear parameters, each with 2-5 options, goal is comprehensive exploration
TRIZ: Clear contradiction (improving A worsens B), need inventive breakthrough
Both: Complex system with parameters AND contradictions

Step 3: Build morphological box (if using MA)

Identify 3-7 independent parameters (changing one doesn't force another)
List 2-5 distinct options per parameter
Create parameter × option matrix

See resources/template.md for structure.

Step 4: Identify contradictions (if using TRIZ)

State clearly:

Improving parameter: What to increase?
Worsening parameter: What degrades?
Look up in TRIZ contradiction matrix

See resources/template.md for 39 TRIZ parameters and contradiction matrix.

Step 5: Apply TRIZ principles

Review 3-4 principles recommended by matrix
Brainstorm applications of each principle
Generate solution concepts
Combine principles for stronger solutions

See resources/template.md for all 40 principles.

For advanced techniques, see resources/methodology.md.

Step 6: Evaluate and select

Morphological: Identify promising combinations, eliminate infeasible, score on objectives, select top 3-5

TRIZ: Assess contradiction resolution, check side effects, estimate difficulty, select most promising

Use resources/evaluators/rubric_morphological_analysis_triz.json for quality criteria.

Common Patterns

Typical Parameters (Examples)

Physical Products: Materials, power source, form factor, control interface, manufacturing method Software: Architecture, data storage, UI, deployment, authentication Services: Delivery channel, pricing model, timing, customization, support level Processes: Automation level, batch size, quality control, scheduling, location

Common Contradictions

Improving ↑	Worsens ↓	Example TRIZ Principles
Speed	Precision	Segmentation, Periodic action
Strength	Weight	Anti-weight, Composite materials
Reliability	Complexity	Segmentation, Beforehand cushioning
Functionality	Ease of use	Segmentation, Universality
Capacity	Size	Nesting, Another dimension

Full principles list: See resources/template.md for all 40.

When to Combine MA + TRIZ

Build morphological box → Find promising configurations
Identify contradictions in top configurations
Apply TRIZ to resolve contradictions
Re-evaluate configurations with contradictions resolved

Guardrails

Morphological Analysis:

Limit parameters: 3-7 parameters (too few = incomplete, too many = explosion)
Ensure independence: Changing one parameter shouldn't force changes in another
Manageable options: 2-5 per parameter (practical range)
Don't enumerate all: Focus on promising clusters

TRIZ:

Verify real contradiction: Improving A truly worsens B (not just budget limit)
Adapt principles: Use as metaphors, not literal prescriptions
Check new contradictions: Solution may introduce new trade-offs
Combine principles: Often need 2-3 together

General:

Document rationale for parameters/options selected
Iterate if first pass reveals missing dimensions
Prototype top concepts - don't just analyze

Quick Reference

Resources:

resources/template.md - Morphological structure, TRIZ contradiction matrix, 40 principles
resources/methodology.md - Advanced TRIZ (trends of evolution, substance-field, ARIZ algorithm)
resources/evaluators/rubric_morphological_analysis_triz.json - Quality criteria

Output: morphological-analysis-triz.md with problem definition, morphological matrix (if used), contradictions, TRIZ principles applied, solution concepts, evaluation, selected solutions

Success Criteria:

Parameters independent and essential (3-7 with 2-5 options each)
Contradictions clearly stated (improving/worsening parameters)
Multiple principles applied per contradiction
Solutions are novel, feasible, address objectives
Top 3-5 selected with rationale
Score ≥ 3.5 on rubric

Quick Decisions:

Simple configuration? → Morphological only
Clear contradiction? → TRIZ only
Complex with trade-offs? → Both methods
Unsure? → Start TRIZ to identify contradictions, then build morphological box

Common Mistakes:

Too many parameters (>7 = explosion)
Dependent parameters (choosing A forces B)
Vague contradiction ("better vs cheaper" - be specific)
Literal TRIZ (principles are metaphors)
No evaluation (generate but don't filter)

Examples:

Morphological (Portable Speaker):

Power: Battery | Solar | Hybrid
Size: Pocket | Handheld | Tabletop
Audio: Mono | Stereo | Surround
Material: Plastic | Metal | Fabric
Control: Button | Touch | Voice | App
Result: 3×3×3×4×4 = 432 configs → Evaluate top 10

TRIZ (Electric Vehicle Range):

Contradiction: Increase range → worsens cost (battery expensive)
Principles: #6 (Universality - battery is structure), #35 (Parameter change - new chemistry)
Solution: Structural battery pack + high energy density cells

Combined:

Build morphological box for EV architecture → Top config has range/cost contradiction → Apply TRIZ Universality principle → Structural battery resolves both range and cost

For detailed principle explanations, contradiction matrix, advanced techniques (substance-field analysis, ARIZ, trends of evolution), and software/service adaptation, see resources/template.md and resources/methodology.md.