Comparison Between Through Hole Assembly & Surface Mount Assembly

 

Introduction

The electronics manufacturing industry has evolved significantly over the decades, with printed circuit board (PCB) assembly methods playing a crucial role in this evolution. Two primary assembly techniques have dominated the industry: Through Hole Assembly (THA) and Surface Mount Assembly (SMA), also known as Surface Mount Technology (SMT). These methodologies represent different approaches to attaching electronic components to printed circuit boards, each with distinct characteristics, advantages, limitations, and suitable applications.

Through Hole Assembly, the older of the two technologies, emerged in the early days of electronic manufacturing and involves components with leads that are inserted through pre-drilled holes in the PCB and soldered on the opposite side. Surface Mount Assembly, which gained popularity in the 1980s, involves placing components directly onto the surface of the PCB without requiring holes, with connections made via solder pads.

This comprehensive comparison explores the fundamental differences between these two assembly methods, examining their historical development, technical processes, advantages and disadvantages, applications, and future trends. Understanding the distinctions between these technologies is essential for engineers, manufacturers, and stakeholders involved in electronic product development to make informed decisions about which assembly method best suits their specific requirements.

Historical Development

The Evolution of Through Hole Assembly

Through Hole Assembly was the standard method for electronic component mounting from the 1950s through the early 1980s. This technology emerged as a solution for creating reliable electrical connections in the early days of electronic manufacturing when components were relatively large and PCBs were simple.

Key milestones in THA development:

• 1940s-1950s: Early implementation of through-hole technology with manual assembly processes
• 1960s: Introduction of wave soldering processes to improve efficiency
• 1970s: Development of automated insertion machines to increase production speeds
• 1980s: Refinement of through-hole processes and tooling as SMT began to emerge

Through Hole Assembly provided several advantages that made it suitable for early electronics manufacturing:

• Strong mechanical bonds
• Relatively simple technology for the time
• Ability to withstand thermal and mechanical stress
• Ease of manual rework and repair

The Rise of Surface Mount Assembly

Surface Mount Technology began gaining traction in the 1980s as electronics miniaturization became increasingly important. The transition was driven by the need for higher component density, smaller devices, and more efficient manufacturing processes.

Key milestones in SMT development:

• Late 1960s: Initial concept development for surface mounting
• 1970s: Early commercial applications of surface mount components
• 1980s: Rapid adoption as manufacturing processes matured
• 1990s: SMT becomes the dominant assembly technology for most electronics
• 2000s-Present: Continuous refinement of SMT processes for ever-smaller components and higher densities

The shift from THA to SMT was revolutionary for electronics manufacturing, enabling:

• Significantly smaller electronic devices
• Higher component density
• Improved automation capabilities
• Better high-frequency performance
• Lower manufacturing costs for high-volume production

Technical Comparison

Through Hole Assembly Process

The Through Hole Assembly process involves several distinct steps:

1. PCB Design and Fabrication: Design includes precisely placed holes for component leads.
2. Component Preparation: Components with leads/pins are prepared for insertion.
3. Component Insertion: Components are inserted into the pre-drilled holes, either manually or by automated insertion machines.
4. Lead Trimming: Excess lead length may be trimmed after insertion.
5. Soldering: Typically accomplished via wave soldering, where the PCB passes over a wave of molten solder.
6. Cleaning: Removal of flux residues and other contaminants.
7. Inspection and Testing: Visual and electrical testing to ensure proper connections.

Surface Mount Assembly Process

The Surface Mount Assembly process follows a different workflow:

1. PCB Design and Fabrication: Design includes solder pads rather than holes.
2. Solder Paste Application: Solder paste is applied to the pads via stencil printing.
3. Component Placement: SMT components are placed on the solder paste using automated pick-and-place machines.
4. Reflow Soldering: The entire assembly passes through a reflow oven where the solder paste melts and forms connections.
5. Cleaning: Removal of flux residues if necessary (many modern processes use no-clean fluxes).
6. Inspection and Testing: Optical and electrical inspection ensures proper placement and connections.

Equipment Requirements

The equipment needs for these two assembly methods differ significantly:

Equipment Type
Through Hole Assembly
Surface Mount Assembly
Insertion Equipment
Component sequencers, axial/radial inserters, manual insertion workstations
Pick-and-place machines, component feeders
Soldering Equipment
Wave soldering machines, selective soldering systems
Reflow ovens, vapor phase soldering systems
Inspection Systems
Visual inspection tools, In-circuit testers
Automated optical inspection (AOI), X-ray inspection, In-circuit testers
Support Equipment
Lead formers, lead trimmers
Solder paste printers, stencils, paste inspection systems
Rework Tools
Soldering irons, desoldering stations
Hot air rework stations, BGA rework systems

Component Types

Each assembly method utilizes distinctly different component packages:

Through Hole Components:

• Dual In-line Packages (DIPs)
• Pin Grid Arrays (PGAs)
• Axial resistors and capacitors
• Radial capacitors
• Conventional transistors (TO packages)
• Through-hole connectors

Surface Mount Components:

• Small Outline Integrated Circuits (SOICs)
• Quad Flat Packages (QFPs)
• Ball Grid Arrays (BGAs)
• Chip resistors and capacitors
• Leadless Chip Carriers (LCCs)
• Surface mount connectors

PCB Design Considerations

PCB design requirements differ substantially between the two technologies:

Design Aspect
Through Hole Assembly
Surface Mount Assembly
Board Thickness
Typically thicker (1.6mm or greater)
Can be very thin (0.4mm-1.6mm)
Hole Requirements
Requires plated through-holes
Minimal or no holes needed for components
Trace Width/Spacing
Generally wider traces
Can accommodate much finer traces
Layer Count
Often simpler, fewer layers
Can support high layer counts
Component Density
Lower density
Much higher density
Thermal Management
Better heat dissipation through leads to both sides
May require thermal vias for heat dissipation

Performance Comparison

Mechanical Strength

Through Hole Assembly offers superior mechanical strength compared to Surface Mount Assembly due to the fundamental differences in how components are attached to the PCB.

Through Hole Strength Factors:

• Components physically anchored through the board
• Solder joints surround the entire lead
• Mechanical stress distributed through the board thickness
• Higher resistance to bending, vibration, and shock

Surface Mount Strength Factors:

• Components attached only to the surface
• Solder joints limited to the contact area with pads
• Mechanical stress concentrated at the surface
• More vulnerable to bending, vibration, and shock without additional protection

For applications subject to extreme mechanical conditions, through-hole components remain advantageous, though various techniques (underfilling, conformal coating, staking) can improve SMT mechanical reliability.

Electrical Performance

Electrical performance characteristics vary significantly between the two technologies:

Performance Aspect
Through Hole Assembly
Surface Mount Assembly
Signal Integrity
Longer leads introduce more inductance and capacitance
Shorter or no leads reduce parasitic effects
High-Frequency Performance
Limited by lead inductance
Superior for RF and high-speed applications
Current Handling
Generally better for high-current applications
Limited by smaller connection areas
Thermal Dissipation
Heat can dissipate through leads to both sides
May require special thermal management
EMI/EMC
Longer leads can act as antennas
Reduced emissions and susceptibility

Reliability Factors

Reliability encompasses multiple factors affecting the long-term performance of electronic assemblies:

Through Hole Reliability Advantages:

• Better withstands thermal cycling
• Superior performance in high-vibration environments
• More resistant to mechanical shock
• Better for high-power applications due to better heat dissipation

Surface Mount Reliability Advantages:

• Fewer holes in PCB means fewer potential failure points
• Better performance in high-frequency applications
• Less susceptible to damage during shipping (when properly packaged)
• Often better in applications with constant, but mild operating conditions

Thermal Considerations

Thermal management differs significantly between the two technologies:

Through Hole Thermal Management:

• Heat can dissipate through component leads to both sides of the PCB
• Component bodies often elevated above the board, allowing better airflow
• Higher thermal mass can help with heat distribution
• Better for high-power components that generate significant heat

Surface Mount Thermal Management:

• Heat primarily dissipates through solder joints to one side of the PCB
• Components in close proximity to the board surface
• May require thermal vias to conduct heat to other layers
• Often requires more sophisticated thermal design for high-power applications

Manufacturing Comparison

Production Speed and Efficiency

Surface Mount Assembly offers significant advantages in manufacturing speed and efficiency compared to Through Hole Assembly:

Manufacturing Aspect
Through Hole Assembly
Surface Mount Assembly
Component Placement Rate
500-5,000 components/hour
10,000-100,000+ components/hour
Setup Time
Longer setup times
Shorter setup times for high-volume production
Automation Potential
Partial automation, often requires manual steps
Nearly complete automation possible
Two-Sided Assembly
Complicated process
Readily achievable
Assembly Line Footprint
Larger space requirements
Smaller space requirements
Production Flow
More process steps
Fewer process steps

Cost Analysis

Cost differences between THA and SMT span various aspects of the manufacturing process:

Component Costs:

• Through-hole components are generally more expensive than equivalent SMT versions
• Through-hole components require more materials (longer leads, larger packages)
• SMT components are produced in much higher volumes, reducing unit costs

Manufacturing Costs:

• Through-hole assembly requires more labor-intensive processes
• SMT equipment has higher initial capital costs but lower operating costs
• SMT offers faster throughput, reducing per-unit manufacturing costs
• SMT requires less factory floor space per production volume

Overall Project Costs:

• Low-volume production may be more economical with through-hole technology
• High-volume production strongly favors SMT
• Mixed-technology assemblies can optimize costs for specific applications

A sample cost comparison for a hypothetical medium-complexity electronic product:

Cost Factor
Through Hole Assembly
Surface Mount Assembly
Component Cost (per unit)
$15.00
$9.50
PCB Cost (per unit)
$3.50
$4.00
Labor Cost (per unit)
$7.00
$2.00
Equipment Depreciation (per unit)
$1.00
$2.50
Testing and Rework (per unit)
$2.50
$1.50
Total Manufacturing Cost (per unit)
$29.00
$19.50

Quality and Defect Rates

Quality metrics show distinct differences between the two technologies:

Through Hole Assembly Defects:

• Misaligned components
• Insufficient solder
• Solder bridges
• Damaged component leads during insertion
• Cracked plated through-holes
• Typical defect rates: 500-1,000 DPMO (Defects Per Million Opportunities)

Surface Mount Assembly Defects:

• Tombstoning (components standing on end)
• Solder bridges
• Insufficient solder
• Component misalignment
• BGA connection issues
• Typical defect rates: 10-100 DPMO with modern equipment

Rework and Repair

The ability to rework and repair assemblies varies significantly between technologies:

Through Hole Rework Advantages:

• Components are easily accessible
• Individual components can be replaced without specialized equipment
• Simpler rework process can be performed with basic tools
• More suitable for field repairs
• Less risk of damaging the PCB during rework

Surface Mount Rework Challenges:

• Requires specialized equipment (hot air stations, infrared heaters)
• More difficult to access components in dense layouts
• Higher risk of damaging adjacent components during rework
• Complex packages (like BGAs) require sophisticated rework stations
• Less suitable for field repairs

Application Domains

Industry-Specific Applications

Different industries leverage the strengths of each assembly technology based on their specific requirements:

Industry
Through Hole Applications
Surface Mount Applications
Aerospace & Defense
Flight-critical systems, high-reliability hardware, extreme environment electronics
Navigation systems, communications equipment, non-critical systems
Automotive
Engine control systems, power electronics, charging systems
Entertainment systems, sensors, dashboard electronics, ECUs
Consumer Electronics
Power supplies, high-current connectors
Smartphones, tablets, wearables, most modern consumer devices
Industrial
Power distribution equipment, industrial control systems, ruggedized interfaces
PLC systems, industrial IoT devices, monitoring equipment
Medical
Life-critical equipment, defibrillators, surgical equipment
Patient monitoring, diagnostic equipment, medical wearables
Telecommunications
Base station power amplifiers, high-power transmission equipment
Network routers, cell phones, communication modules
Military
Battlefield equipment, missile guidance systems, submarine electronics
Communication devices, reconnaissance equipment, tactical systems

Scenario-Based Selection Criteria

The choice between THA and SMT often depends on specific project parameters:

Favor Through Hole When:

• The product will operate in high-vibration environments
• Extreme temperatures are expected in operation
• Very high current or voltage handling is required
• Field serviceability is important
• Low volume, high mix production is planned
• The product has a long life cycle with infrequent redesigns

Favor Surface Mount When:

• Miniaturization is a primary goal
• High-density component placement is required
• High-frequency performance is critical
• High-volume production is planned
• Automated manufacturing is essential
• Weight reduction is important
• Component cost is a significant factor

Mixed Technology Approaches

Many modern electronic products utilize both technologies to leverage their respective advantages:

Common Mixed Technology Strategies:

• Through-hole connectors and power components with SMT for logic and signal processing
• Through-hole for mechanical stress points and SMT for everything else
• SMT on both sides with selective through-hole components where needed
• Through-hole for legacy or specialized components, SMT for standard components

Examples of effective mixed technology implementations:

1. Power Supplies: SMT control circuitry with through-hole transformers and high-power components
2. Industrial Controls: Through-hole connectors and input protection with SMT processors and I/O circuitry
3. Computer Motherboards: Through-hole for sockets and connectors, SMT for processors, memory, and support chips
4. Automotive Electronics: Through-hole for high-current connections, SMT for sensors and control circuitry

Environmental and Sustainability Considerations

Material Usage and Waste

The two assembly methods have different environmental footprints in terms of material consumption and waste generation:

Through Hole Assembly:

• Requires more raw materials for component manufacturing (longer leads, larger packages)
• PCBs require more copper and substrate material due to holes and larger footprints
• Typically uses more solder material per joint
• Often uses more cleaning agents in the manufacturing process

Surface Mount Assembly:

• Reduced material usage for components and PCBs
• Smaller solder volume requirements
• Lower chemical cleaning requirements with no-clean fluxes
• Higher component density reduces overall material usage per function

Energy Consumption

Energy requirements differ between the two technologies:

Process Stage
Through Hole Energy Profile
Surface Mount Energy Profile
PCB Manufacturing
Higher energy due to drilling
Lower energy with fewer holes
Component Production
Higher energy per component
Lower energy per component
Assembly Process
Wave soldering uses more energy
Reflow requires less total energy
Equipment Operation
Higher per-unit energy consumption
More efficient per-unit energy use
Total Lifecycle
Generally higher energy footprint
Reduced overall energy requirements

End-of-Life Considerations

The recyclability and end-of-life handling of electronic assemblies vary between technologies:

Through Hole Recycling Considerations:

• Components can be more easily removed and reused
• Better for repair and refurbishment scenarios
• Larger components are easier to sort in recycling processes
• Often contains more recoverable material per board

Surface Mount Recycling Challenges:

• More difficult to separate components for reuse
• Higher component density can complicate material separation
• Smaller components are more challenging to sort in recycling
• More efficient material use can mean less recoverable material

Compliance with Environmental Regulations

Both technologies have had to adapt to environmental regulations, particularly regarding lead-free manufacturing:

RoHS and REACH Compliance Challenges:

• Through-hole assemblies typically experienced more reliability issues in the transition to lead-free solder
• Higher thermal mass in through-hole components requires higher soldering temperatures
• Surface mount processes adapted more readily to lead-free requirements
• Both technologies now have established lead-free manufacturing processes

Future Trends and Developments

Technology Evolution

Both assembly methods continue to evolve, though at different paces:

Through Hole Technology Evolution:

• Selective soldering technology improvements
• Automated through-hole insertion advancements
• Development of more reliable lead-free through-hole processes
• Specialty through-hole components for specific applications

Surface Mount Technology Evolution:

• Continuous miniaturization (01005, 008004 components)
• Embedded component technologies
• Advancement in package-on-package (PoP) technologies
• Development of new thermal management approaches

Emerging Hybrid Approaches

The industry is developing innovative approaches that combine aspects of both technologies:

1. Press-Fit Technology: Through-hole-like mechanical robustness without soldering
2. Pin-in-Paste Process: Through-hole components soldered in reflow ovens alongside SMT
3. Embedded Component Technology: Components embedded within PCB layers
4. Intrusive Reflow Soldering: Through-hole components soldered via reflow

Impact of Industry 4.0 and Smart Manufacturing

The evolution of smart manufacturing affects both assembly technologies:

Through Hole Assembly in Industry 4.0:

• Automated optical inspection for through-hole solder joints
• AI-driven process optimization for wave soldering
• Digital twin modeling of through-hole manufacturing processes
• Connected through-hole insertion equipment for production monitoring

Surface Mount Assembly in Industry 4.0:

• Advanced process control with real-time feedback
• AI-driven component placement optimization
• Predictive maintenance for SMT equipment
• Complete traceability through connected factory systems

Predictions for the Next Decade

Industry experts project several trends for the next decade:

1. Through Hole Technology:
   • Continued presence but further reduction in market share
   • Specialization for high-reliability and high-power applications
   • Improved automation to reduce cost differential with SMT
   • Integration with additive manufacturing techniques
2. Surface Mount Technology:
   • Further miniaturization beyond current limits
   • Increased integration with printed electronics
   • Development of new package types for specialized applications
   • Greater focus on environmentally sustainable processes

Decision Framework for Assembly Method Selection

Technical Requirements Assessment

When deciding between assembly methods, organizations should evaluate:

1. Electrical Requirements:
   • Voltage and current handling needs
   • Signal integrity requirements
   • EMI/EMC considerations
   • Thermal management needs
2. Mechanical Requirements:
   • Vibration and shock resistance needs
   • Operating environment conditions
   • Physical size constraints
   • Weight limitations
3. Reliability Requirements:
   • Expected product lifespan
   • Operating temperature range
   • Environmental exposure (humidity, dust, chemicals)
   • Criticality of application

Business and Operational Factors

Beyond technical considerations, business factors significantly influence the decision:

Production Volume Considerations:

Production Volume
Through Hole Viability
Surface Mount Viability
Prototyping
Highly viable - easier to assemble manually
Viable with appropriate equipment
Low Volume (<1,000 units/year)
Often more economical
May require higher initial investment
Medium Volume (1,000-10,000 units/year)
Viable but less efficient
Generally more economical
High Volume (>10,000 units/year)
Less economical except for specific applications
Highly economical

Supply Chain Considerations:

• Component availability and lead times
• Vendor ecosystem and support
• Future component obsolescence risk
• Geographic accessibility of manufacturing support

Lifecycle Management:

• Expected product lifespan
• Anticipated revision frequency
• Field serviceability requirements
• End-of-life strategy

Decision Matrix Template

The following decision matrix can help organizations evaluate which assembly technology best meets their needs:

Decision Factor
Weight (1-10)
Through Hole Score (1-10)
Surface Mount Score (1-10)
Weighted TH Score
Weighted SMT Score
Electrical Performance
Mechanical Durability
Miniaturization Needs
Production Volume
Manufacturing Capability
Component Availability
Design Flexibility
Thermal Requirements
Cost Constraints
Time-to-Market
TOTALS

Organizations can customize this matrix with their specific requirements, assigning weights and scores based on their unique situation.

Case Studies

Aerospace Application: Flight Control Systems

Challenge: An aerospace company needed to develop flight control electronics for a new commercial aircraft, requiring extremely high reliability under varying environmental conditions while managing costs.

Solution:

• Critical control circuits: Through-hole components for maximum vibration resistance
• Monitoring and diagnostic systems: SMT for higher functionality in limited space
• Power distribution: Through-hole for high current handling
• Interface systems: Mixed technology with through-hole connectors and SMT circuitry

Results:

• Achieved 99.999% reliability target
• Reduced weight by 15% compared to previous all-through-hole design
• Maintained serviceability for critical components
• Extended operational temperature range

Consumer Electronics: Smartphone Design

Challenge: A smartphone manufacturer needed to maximize functionality in an ultra-thin device while ensuring manufacturing efficiency for millions of units.

Solution:

• Main PCB: Pure SMT design with components on both sides
• Battery connections: Specialized surface mount connectors
• Antenna design: Embedded traces and surface mount components
• Audio system: Miniaturized surface mount speakers and amplifiers

Results:

• Achieved 7.5mm thickness target
• Incorporated multiple antennas, sensors, and high-performance processor
• Manufacturing yield exceeded 99%
• Automated testing detected defects with 99.8% accuracy

Industrial Equipment: Factory Automation Controller

Challenge: An industrial manufacturer needed to develop a control system that could withstand harsh factory environments while providing advanced functionality and field serviceability.

Solution:

• Power section: Through-hole components for durability and heat dissipation
• CPU and memory: Surface mount for performance and density
• I/O connections: Through-hole for mechanical strength
• Communication modules: Surface mount for high-speed performance

Results:

• System withstood temperatures from -20°C to +70°C
• Vibration resistance exceeded industry standards
• Field technicians could replace critical components on-site
• 10-year product lifecycle achieved without major redesigns

Medical Device: Portable Monitoring Equipment

Challenge: A medical device company needed to develop a portable patient monitoring system combining reliability with miniaturization and power efficiency.

Solution:

• Sensor interfaces: Through-hole for critical connections
• Main processing board: Pure SMT for miniaturization
• Power management: Mixed technology with through-hole for high-current components
• User interface: Flexible PCB with SMT for display connectivity

Results:

• Achieved medical-grade reliability standards
• Battery life extended by 30% through efficient design
• Device weight reduced by 40% compared to previous generation
• Manufacturing costs reduced by 25% through optimized assembly

Frequently Asked Questions

Q1: When should I choose Through Hole Assembly over Surface Mount Assembly?

A: Through Hole Assembly is generally preferable in the following scenarios:

• When your product will operate in high-vibration or high-shock environments
• For high-power applications requiring superior thermal dissipation
• When mechanical strength of component attachment is critical
• For products that require field serviceability by technicians with basic tools
• When producing in low volumes where the investment in SMT equipment isn't justified
• For projects using specialized components only available in through-hole packages
• When extreme operating temperatures are expected

Consider that many designs can benefit from a mixed-technology approach, using through-hole components where their strengths are needed while leveraging SMT elsewhere.

Q2: How does the cost compare between Through Hole and Surface Mount Assembly?

A: Cost comparison between the two technologies depends on several factors:

Component Costs:

• Surface mount components are typically 20-50% less expensive than their through-hole equivalents
• High-volume production favors the cost advantages of SMT
• For low volumes, the component cost difference may be offset by equipment requirements

Manufacturing Costs:

• Through-hole assembly generally has higher labor costs due to more manual processes
• SMT requires more expensive equipment but offers higher throughput
• For high volumes, SMT manufacturing costs per unit are substantially lower
• For prototypes or very low volumes, through-hole may be more economical

Total Cost Consideration: For high-volume production (thousands of units or more), SMT almost always offers the lowest total cost. For very low volumes or prototypes, through-hole might be more economical when considering setup costs. The crossover point varies by product complexity but typically occurs in the hundreds to low thousands of units.

Q3: Can Through Hole and Surface Mount technologies be used together on the same PCB?

A: Yes, combining both technologies on a single PCB is common practice and is referred to as "mixed technology" assembly. This approach allows designers to leverage the advantages of each technology where appropriate.

Common mixed-technology implementations include:

• Through-hole connectors and power components with SMT for logic and control circuitry
• Through-hole for components requiring mechanical strength with SMT for everything else
• SMT on both sides of the board with selective through-hole components
• Through-hole for specialized or legacy components with SMT for standard components

Manufacturing Considerations for Mixed Technology:

• Requires careful process planning (typically SMT first, followed by through-hole)
• May involve multiple soldering processes (reflow for SMT, followed by selective or wave soldering for through-hole)
• Advanced techniques like Pin-in-Paste can allow through-hole components to be reflowed alongside SMT components
• Design must account for process compatibility and thermal management

Mixed technology approaches offer an optimal solution for many applications, though they may increase manufacturing complexity.

Q4: How does reliability compare between Through Hole and Surface Mount Assembly?

A: Reliability comparisons depend on the specific environmental and operational conditions:

Mechanical Reliability:

• Through-hole connections generally offer superior mechanical strength
• Through-hole assemblies typically withstand vibration and physical shock better
• SMT reliability in mechanical stress scenarios can be improved with underfill, conformal coating, or staking adhesives

Thermal Reliability:

• Through-hole components typically handle thermal cycling better due to stress distribution
• SMT components with appropriate design considerations can achieve excellent thermal reliability
• For extreme temperature applications, through-hole often maintains an advantage

Long-term Reliability:

• Modern SMT processes can achieve excellent long-term reliability in controlled environments
• For harsh environments, through-hole may offer better long-term performance
• Proper design is more important than the technology choice for long-term reliability

Reliability Data: Mean Time Between Failures (MTBF) data shows that well-designed and properly manufactured assemblies using either technology can achieve high reliability. The specific application requirements and environmental conditions should guide the technology selection more than generalized reliability comparisons.

Q5: What is the future outlook for Through Hole Technology given the dominance of Surface Mount?

A: Despite the prevalence of SMT in modern electronics manufacturing, Through Hole Technology continues to have a secure place in the industry for the foreseeable future. Here's the outlook:

Continued Relevance:

• Through-hole components remain essential for high-power applications
• Connectors, transformers, and other mechanical interface components often use through-hole mounting
• Harsh environment applications continue to benefit from through-hole reliability advantages
• Military and aerospace specifications still often require through-hole for critical systems

Evolution Rather Than Extinction:

• Through-hole processes are becoming more automated and efficient
• Selective soldering technology continues to improve
• Hybrid approaches like Pin-in-Paste are bridging the gap between technologies
• Through-hole is finding specialized niches rather than disappearing

Market Trajectory: While SMT now accounts for approximately 90% of component placements globally, through-hole technology is stabilizing at a smaller but significant percentage of the market. Rather than disappearing, it is becoming more specialized for applications where its advantages are most valuable.

Future Developments: We can expect continued development of specialized through-hole components and assembly techniques focused on the specific advantages of through-hole technology, particularly in high-reliability, high-power, and extreme environment applications.

Conclusion

The comparison between Through Hole Assembly and Surface Mount Assembly reveals that each technology has distinct advantages and continues to play important roles in electronics manufacturing. Rather than viewing them as competing technologies where one will eventually replace the other, the industry has evolved to use each where its strengths provide the most benefit.

Surface Mount Technology has undoubtedly become the dominant assembly method for most applications due to its miniaturization capabilities, manufacturing efficiency, and cost advantages in high-volume production. SMT has enabled the remarkable miniaturization of electronic devices that we now take for granted, from smartphones to wearable technology.

Through Hole Technology, despite declining in overall market share, continues to provide critical advantages in specific applications and shows no signs of disappearing. Its superior mechanical strength, thermal performance, and serviceability ensure its continued relevance for high-reliability, high-power, and harsh environment applications.

The most successful approach for many modern electronic products is a thoughtful combination of both technologies, leveraging SMT for miniaturization and density while using through-hole components where their strengths in power handling, connector reliability, or mechanical durability are required.

As electronics continue to evolve, manufacturers and designers should maintain proficiency in both technologies, understanding their respective strengths, limitations, and optimal applications. This balanced approach will enable the creation of electronic products that offer the best combination of functionality, reliability, manufacturability, and cost-effectiveness.