IPC-6901: Printed Electronics Categories, Levels & Performance Criteria by Application

When you’re developing a printed electronics product, one of the first questions that comes up is: what performance requirements apply to my application? A medical sensor has vastly different reliability demands than a smart packaging tag. IPC-6901 provides the classification framework that answers this question, establishing market categories and assembly levels that define appropriate performance criteria for printed electronics across every major industry segment.

Having worked with printed electronics projects spanning consumer wearables to automotive sensors, I’ve found IPC-6901 indispensable for setting realistic performance targets and communicating requirements to suppliers. This guide explains how to use the standard’s dual classification system effectively.

What is IPC-6901?

IPC-6901, officially titled “Application Categories for Printed Electronics,” is a joint IPC/JPCA standard that establishes classification systems for printed electronics products and assemblies. Published in July 2015, IPC-6901 was developed by the Printed Electronics Final Assembly Subcommittee (D-64) in collaboration with the JPCA Printed Electronics Committee.

Document Attribute	IPC-6901 Details
Full Title	Application Categories for Printed Electronics
Document Number	IPC/JPCA-6901
Joint Development	IPC and JPCA
Publication Date	July 2015
Developed By	Printed Electronics Final Assembly Subcommittee (D-64)
Primary Purpose	Classification systems and performance criteria

Unlike traditional PCB standards that focus on manufacturing specifications, IPC-6901 takes an application-centric approach. The standard helps engineers classify their printed electronics products by market segment and assembly complexity, then provides appropriate performance criteria and testing methods for each classification.

Purpose and Scope of IPC-6901

The primary purpose of IPC-6901 is to provide printed electronics developers with a structured classification framework for designing and manufacturing products that conform to industry-established performance metrics. The standard accomplishes this through three key elements.

Market Classification System: Eleven categories covering major application sectors from aerospace to smart packaging.

Level Classification System: Four levels defining assembly complexity from passive components to complete products.

Performance Framework: Lists of performance criteria and testing methods applicable to each classification.

IPC-6901 applies to both traditional printed electronics (fully printed circuitry) and Flexible Hybrid Electronics (FHE) that combine printed and conventional components. This dual coverage reflects the reality that most commercial printed electronics products incorporate some conventional elements.

IPC-6901 Market Classification System

The IPC-6901 market classification system organizes printed electronics applications into eleven categories based on end-use market segment. Each category carries different performance expectations and regulatory requirements that influence design decisions.

Category Overview Table

Category	Market Segment	Key Characteristics
1	Aerospace	Extreme reliability, harsh environments
2	Automotive	Temperature extremes, vibration, long life
3	Consumer Electronics & Communications	Cost-sensitive, moderate reliability
4	Home/Domestic Robotics	Safety-critical, consumer interaction
5	Industrial & Commercial Controls	Durability, environmental exposure
6	Medical	Biocompatibility, regulatory compliance
7	Military	Extreme conditions, mission-critical
8	Building Materials	Long service life, environmental stability
9	Smart Packaging	Low cost, single use, food safety
10	Smart Grid	Outdoor exposure, grid integration
11	Future	Emerging applications

Aerospace Applications (Category 1)

Category 1 covers printed electronics for aerospace applications where failure is not an option. These products must operate reliably in extreme conditions including rapid temperature cycling, high altitude pressure differentials, radiation exposure, and significant vibration loads.

Typical Applications:

• Structural health monitoring sensors
• Cabin environmental sensors
• Lightweight wiring harness replacements
• Conformal antenna systems

Performance Priorities: Reliability under thermal cycling, radiation tolerance, weight reduction, vibration resistance.

Automotive Applications (Category 2)

Category 2 addresses the automotive industry’s demanding requirements for printed electronics. Automotive applications face temperature extremes from cold-start conditions to under-hood heat, continuous vibration exposure, and expected service lives often exceeding 15 years.

Typical Applications:

• Interior touch surfaces and controls
• Seat occupancy sensors
• In-mold electronics for dashboards
• Flexible heating elements
• Battery monitoring systems for EVs

Performance Priorities: Wide temperature range operation, vibration durability, long service life, automotive qualification testing (AEC-Q).

Consumer Electronics and Communications (Category 3)

Category 3 encompasses the high-volume consumer electronics market where printed electronics enables new form factors and reduces manufacturing costs. Cost optimization often takes priority over extreme reliability requirements.

Typical Applications:

• Wearable device circuits
• Flexible display backplanes
• Touch sensors for mobile devices
• RFID tags and NFC antennas
• Printed batteries for IoT devices

Performance Priorities: Cost efficiency, manufacturing scalability, adequate reliability for consumer expectations (typically 2-5 year product life).

Home and Domestic Robotics (Category 4)

Category 4 addresses emerging applications in home robotics and automated domestic systems. These applications combine consumer product expectations with safety requirements for human interaction.

Typical Applications:

• Robot vacuum sensor arrays
• Smart home environmental sensors
• Automated pet care devices
• Personal assistance robots
• Home security sensor networks

Performance Priorities: Human safety in close proximity, reliable operation in home environments, dust and moisture resistance.

Industrial and Commercial Controls (Category 5)

Category 5 covers industrial applications where printed electronics enable distributed sensing, flexible controls, and harsh environment operation. These applications typically require longer service lives than consumer products and may face chemical exposure or extreme temperatures.

Typical Applications:

• Manufacturing process sensors
• Industrial equipment HMIs
• Environmental monitoring systems
• Asset tracking and identification
• Condition monitoring for predictive maintenance

Performance Priorities: Chemical resistance, extended operating temperature range, reliability in industrial environments, electromagnetic compatibility.

Medical Applications (Category 6)

Category 6 addresses medical applications with their unique regulatory requirements and biocompatibility considerations. Medical printed electronics span from single-use diagnostic devices to long-term implantables.

Typical Applications:

• Disposable diagnostic test strips
• Wearable patient monitoring patches
• Smart wound dressings
• Drug delivery patches
• Prosthetic sensor interfaces

Performance Priorities: Biocompatibility, sterilization compatibility, regulatory compliance (FDA, CE marking), reliability for patient safety.

Military Applications (Category 7)

Category 7 encompasses military and defense applications where printed electronics must operate in the most demanding environments while meeting strict military specifications.

Typical Applications:

• Soldier-worn sensor systems
• Conformal antennas for vehicles
• Structural health monitoring
• Unmanned vehicle systems
• Field-deployable electronics

Performance Priorities: Extreme environment operation, MIL-SPEC compliance, reliability under combat conditions, rapid deployment capability.

Building Materials Applications (Category 8)

Category 8 covers printed electronics integrated into building materials and architectural elements. These applications require exceptional service life measured in decades rather than years.

Typical Applications:

• Smart windows with integrated sensors
• Building envelope monitoring
• Integrated lighting controls
• Structural strain monitoring
• HVAC zone sensors

Performance Priorities: 20+ year service life, UV stability, moisture resistance, integration with construction materials.

Smart Packaging Applications (Category 9)

Category 9 addresses the rapidly growing smart packaging market where printed electronics adds intelligence to product packaging. Cost constraints are typically severe, and many applications are single-use.

Typical Applications:

• Temperature monitoring labels
• Freshness indicators for food
• Anti-counterfeiting tags
• Interactive product packaging
• Supply chain tracking

Performance Priorities: Ultra-low cost, food-safe materials, single-use reliability, recyclability considerations.

Smart Grid Applications (Category 10)

Category 10 covers printed electronics for electrical grid monitoring and control. These applications face outdoor exposure and must interface reliably with electrical infrastructure.

Typical Applications:

• Power line monitoring sensors
• Transformer health sensors
• Solar panel monitoring
• Grid-connected storage monitoring
• Demand response systems

Performance Priorities: Outdoor durability, electrical safety, long service life, electromagnetic compatibility with grid systems.

Future Applications (Category 11)

Category 11 provides a placeholder for emerging applications that don’t fit existing categories. As printed electronics technology evolves, new market segments will emerge that require their own classification criteria.

IPC-6901 Level Classification System

Beyond market categories, IPC-6901 establishes a level classification system that defines the complexity and integration state of printed electronics assemblies. This four-level system applies to both fully printed electronics and Flexible Hybrid Electronics (FHE).

Level Classification Overview

Level	Assembly Type	Description
1	Passive Components	Basic printed elements (resistors, capacitors, antennas)
2	Active Components	Printed elements with active function (transistors, diodes)
3	Modules	Integrated subsystems combining multiple components
4	Final Products	Complete functional products ready for end use

Level 1: Printed and FHE Passive Components

Level 1 covers the most basic printed electronics elements that provide passive electrical functions. These components form the building blocks for more complex assemblies.

Printed Passive Components:

• Printed resistors
• Printed capacitors
• Printed inductors
• Printed antennas and RFID coils
• Printed interconnects and traces

FHE Passive Components:

• Hybrid circuits with printed passives and conventional interconnects
• Printed antennas with conventional matching networks
• Sensor electrodes with printed conductors

Level 2: Printed and FHE Active Components

Level 2 encompasses printed electronics with active device functionality. These components can amplify, switch, or otherwise actively process signals.

Printed Active Components:

• Printed thin-film transistors (TFTs)
• Printed diodes
• Printed photodetectors
• Organic LEDs (OLEDs)
• Electrochromic displays

FHE Active Components:

• Hybrid circuits combining printed elements with conventional ICs
• Printed sensor arrays with conventional signal processing
• Flexible circuits with attached silicon chips

Level 3: Printed and FHE Modules

Level 3 covers integrated subsystems that combine multiple components into functional modules. Modules provide defined functionality but are not complete end products.

Printed Modules:

• Printed sensor modules with integrated processing
• Display modules with driver circuitry
• Printed battery systems with management circuits
• Communication modules with antenna and logic

FHE Modules:

• Sensor systems combining printed sensors with conventional MCUs
• Power management modules with printed energy harvesting
• Wireless modules integrating printed antennas with conventional RF ICs

Level 4: Printed and FHE Final Products

Level 4 represents complete products ready for end-user deployment. Final products incorporate all necessary functionality including power, sensing, processing, and interfaces.

Printed Final Products:

• Complete wearable health monitors
• Standalone smart packaging solutions
• Integrated sensor systems with wireless communication
• Consumer electronic devices

FHE Final Products:

• Medical patches with complete diagnostic capability
• Automotive sensor assemblies ready for vehicle integration
• Industrial monitoring systems for direct deployment

Flexible Hybrid Electronics in IPC-6901

IPC-6901 explicitly addresses Flexible Hybrid Electronics (FHE), recognizing that most commercial printed electronics products combine printed and conventional components. The standard includes FHE definitions and applies classification systems equally to pure printed electronics and hybrid approaches.

Key FHE Terms Defined in IPC-6901

Term	Definition
Flexible Hybrid Electronics	Electronics combining printed/flexible elements with conventional components
Front-End Assembly	Printing and deposition processes for creating circuitry
Back-End Assembly	Component attachment and final integration processes
Post Processing	Treatment after printing (sintering, curing, encapsulation)
Stretchable Electronics	Circuits designed to accommodate mechanical stretching
Wearable Electronics	Electronics designed for body-worn applications

Understanding these distinctions matters because FHE products often face different testing requirements than fully printed alternatives. The combination of printed and conventional elements creates unique reliability considerations at material interfaces.

Performance Criteria and Testing Methods

IPC-6901 establishes categories of performance criteria applicable to printed electronics, with specific tests selected based on market category and assembly level. The standard provides a framework rather than mandating specific tests, allowing flexibility for application-specific requirements.

Performance Criteria Categories

Category	Scope	Example Tests
Chemical Resistance	Exposure to chemicals, solvents, cleaning agents	Solvent resistance, chemical spot tests
Electrical	Functional electrical performance	Continuity, insulation resistance, high-pot
Mechanical	Physical durability and integrity	Flexure, drop, vibration, adhesion
Operation	In-use functional performance	Burn-in, functional test, environmental
Reliability	Long-term performance stability	Accelerated aging, HALT/HASS
Safety	Human and environmental safety	Biocompatibility, flammability, toxicity
Visual	Cosmetic appearance criteria	Defect inspection, surface quality

Chemical Resistance Testing

Chemical resistance testing verifies that printed electronics assemblies can withstand exposure to chemicals encountered during manufacturing, assembly, and end use. For medical applications, this includes sterilization chemicals. For industrial applications, process chemicals and cleaning solvents are relevant.

Electrical Testing

Electrical testing confirms that printed circuits meet functional requirements. Unlike traditional PCBs, printed electronics often exhibit higher resistance values and greater variability, requiring adapted test limits and methods.

Key Electrical Tests:

• Conductor resistance and uniformity
• Insulation resistance between circuits
• Dielectric withstand voltage
• High-frequency performance (for antennas, RF circuits)
• Component functionality

Mechanical Testing

Mechanical testing addresses the unique flexibility and conformability characteristics of printed electronics. Standard rigid PCB mechanical tests are often inappropriate for flexible substrates.

Key Mechanical Tests:

• Flexure testing (static and dynamic bending)
• Drop testing
• Vibration testing
• Adhesion testing (conductor to substrate)
• Abrasion resistance
• Crease resistance

Reliability Testing

Reliability testing accelerates aging mechanisms to predict long-term performance. Test conditions should reflect the actual use environment defined by the market category.

Common Reliability Tests:

• Temperature cycling
• Humidity exposure (steady-state and cycling)
• Combined temperature/humidity/bias
• Mechanical fatigue (repeated flexing)
• UV exposure (for outdoor applications)

Safety Testing

Safety testing requirements vary significantly by market category. Medical and food-contact applications require biocompatibility and toxicity testing. Consumer products require flammability testing. All products must meet applicable regulatory safety requirements.

Quality Assurance Provisions in IPC-6901

IPC-6901 establishes quality assurance requirements adapted to printed electronics manufacturing. These provisions address the unique characteristics of printed electronics while maintaining compatibility with established quality systems.

Quality System Requirements

Requirement	Description
Responsibility for Inspection	Defines who performs inspection activities
Responsibility for Compliance	Establishes compliance accountability
Quality Assurance Program	Requires documented quality program
Test Equipment	Calibration and maintenance requirements
Sample Preparation	Standard methods for test sample preparation
Laboratory Conditions	Environmental requirements for testing

Qualification vs. Conformance Testing

IPC-6901 distinguishes between qualification inspection (initial product validation) and quality conformance inspection (ongoing production verification).

Qualification Inspection:

• Comprehensive testing of initial production
• Validates that design meets performance requirements
• Typically extensive testing of limited samples
• Required before production release

Quality Conformance Inspection:

• Ongoing verification during production
• Sampling-based inspection of production lots
• Primary and secondary inspection provisions
• Statistical process control options

Statistical Process Control

IPC-6901 supports statistical process control (SPC) as an alternative to end-of-line inspection. When manufacturers demonstrate process capability through SPC, the standard allows reduced quality conformance testing frequency.

Using IPC-6901 Classification in Practice

Applying IPC-6901 requires determining both market category and assembly level for your product. This dual classification drives performance requirements and testing strategy.

Classification Decision Process

Step 1: Determine Market Category Identify the primary end-use market for your product. If multiple markets apply, use the most demanding category.

Step 2: Determine Assembly Level Assess whether your product is a component (Level 1-2), module (Level 3), or final product (Level 4).

Step 3: Identify Performance Requirements Based on category and level, determine applicable performance criteria.

Step 4: Select Test Methods Choose appropriate test methods from IPC-6901 framework or industry-specific standards.

Step 5: Document in Procurement Include classification and requirements in procurement documentation.

Example Classification

Consider a printed glucose sensor patch for diabetic monitoring:

Classification Element	Selection
Market Category	Category 6 (Medical)
Assembly Level	Level 4 (Final Product)
Key Performance Criteria	Biocompatibility, electrical accuracy, adhesion
Regulatory Considerations	FDA 510(k), ISO 13485, biocompatibility testing
Critical Tests	Cytotoxicity, sensitization, skin irritation, electrical

IPC-6901 and Related Printed Electronics Standards

IPC-6901 functions within a broader ecosystem of printed electronics standards. Understanding these relationships helps engineers apply the complete framework effectively.

Printed Electronics Standards Ecosystem

Standard	Title	Relationship to IPC-6901
IPC-2291	Design Guideline for Printed Electronics	Design guidance for PE products
IPC-2292	Design Standard for PE on Flexible Substrates	Detailed design requirements
IPC-4591	Requirements for Functional Conductive Materials	Ink and paste specifications
IPC-4921	Requirements for PE Base Materials	Substrate specifications
IPC-6902	Qualification and Performance Specification	Detailed qualification requirements
IPC-6903	Terms and Definitions for PE	Common terminology
IPC-9204	Flexibility and Stretchability Testing	Test methods for flex/stretch

IPC-6901 vs IPC-6902

IPC-6901 establishes classification categories and general performance frameworks. IPC-6902 provides detailed qualification and performance specifications for products classified using IPC-6901. Think of IPC-6901 as answering “what category is my product?” while IPC-6902 answers “exactly what tests must it pass?”

Useful Resources for IPC-6901 Implementation

Official IPC Resources

Resource	URL	Description
IPC-6901 Standard	https://shop.ipc.org	Official standard purchase
IPC-6902 Standard	https://shop.ipc.org	Companion qualification spec
IPC Standards Tree	https://www.ipc.org	Standards relationship guide
IPC Table of Contents	https://www.ipc.org/TOC/IPC-JPCA-6901-toc.pdf	Free preview

Industry Organizations

Organization	URL	Focus
NextFlex	https://www.nextflex.us	US FHE manufacturing institute
FlexTech/SEMI	https://www.semi.org/en/communities/flextech	FHE standards consortium
OE-A	https://www.oe-a.org	European organic/printed electronics
JPCA	https://www.jpca.org	Japanese printed circuits association

Related Test Method Standards

Standard	Scope
ASTM F1842	Ink/coating adhesion on flexible substrates
ASTM F1896	Electrical resistivity of printed conductors
ASTM F2749	Creasing effects on printed electronics
ASTM F2750	Bending effects on printed electronics
IEC 62899 series	Printed electronics test methods

Frequently Asked Questions About IPC-6901

What is the difference between IPC-6901 and IPC-6902?

IPC-6901 establishes the classification system for printed electronics, defining market categories and assembly levels. It provides a framework for identifying what performance criteria apply to different product types. IPC-6902 is the companion qualification and performance specification that provides detailed test requirements and acceptance criteria for products classified using IPC-6901. You typically use IPC-6901 first to classify your product, then reference IPC-6902 for specific qualification requirements.

How do I classify a product that serves multiple markets?

When a printed electronics product serves multiple market categories, IPC-6901 recommends using the most demanding category to establish performance requirements. For example, a sensor used in both consumer wearables (Category 3) and medical monitoring (Category 6) should be designed and tested to Category 6 medical requirements. This ensures the product meets the highest applicable standards.

Does IPC-6901 apply to traditional flexible circuits?

IPC-6901 specifically addresses printed electronics and Flexible Hybrid Electronics (FHE), not traditional etched flexible circuits. Traditional flex circuits are covered by IPC-6013 (Qualification and Performance Specification for Flexible Printed Boards). However, hybrid products combining printed elements with traditional flex circuit construction may reference both standards.

What testing is required for IPC-6901 compliance?

IPC-6901 establishes performance criteria categories but does not mandate specific tests for all products. The appropriate tests depend on market category and assembly level. The standard provides a framework that users adapt to their specific application. For detailed test requirements, reference IPC-6902 and application-specific standards (e.g., ISO 10993 for medical biocompatibility).

How does IPC-6901 address emerging applications?

IPC-6901 includes Category 11 (Future) specifically for emerging applications that don’t fit existing market categories. As new applications develop, users can apply the general framework of performance criteria categories while the standard evolves to add specific guidance. IPC encourages users to submit information on new applications to help guide future standard revisions.

Implementing IPC-6901 in Your Organization

Successfully implementing IPC-6901 requires coordination across product development, quality, and supply chain functions.

Design Engineering

• Determine market category early in product development
• Use category to establish design requirements
• Reference level classification for appropriate complexity
• Document classification in design specifications

Quality Engineering

• Develop test plans based on IPC-6901 performance criteria
• Establish qualification protocols aligned with classification
• Implement conformance testing appropriate to production
• Consider SPC for process-capable operations

Procurement

• Include IPC-6901 classification in supplier requirements
• Specify category and level in purchase orders
• Require supplier compliance with applicable criteria
• Establish incoming inspection based on classification

Conclusion

IPC-6901 provides the essential classification framework for printed electronics products, enabling engineers to systematically identify performance requirements based on application and assembly complexity. The standard’s dual classification system—eleven market categories and four assembly levels—creates a structured approach to product development that ensures appropriate reliability and performance for each application.

For printed electronics engineers, understanding IPC-6901 is fundamental to successful product development. Whether you’re designing a medical diagnostic patch, an automotive interior sensor, or a smart packaging indicator, IPC-6901 helps you identify what matters for your specific application. Combined with companion standards like IPC-6902 for detailed qualification requirements and IPC-4591/IPC-4921 for materials, IPC-6901 forms the backbone of the printed electronics standards ecosystem.

The printed electronics industry continues to evolve rapidly, with new applications emerging regularly. IPC-6901’s framework provides stability for established applications while accommodating innovation through its Category 11 provisions for future applications. As you develop printed electronics products, start with IPC-6901 classification to establish the foundation for successful product development.