Understanding Shock Testing Types: From Classical Pulse to Ballistic Shock
Advanced shock testing setup at Infinita Lab ensuring accurate product performance evaluationShock testing subjects products and components to sudden, high-intensity transient forces that simulate real-world events, including drops, transportation impacts, pyrotechnic events, earthquakes, and ballistic loading. Different shock test types use different pulse shapes, equipment, and standards depending on the application and the type of shock environment being simulated. For manufacturers seeking shock testing at a US-based testing lab, Infinita Lab provides comprehensive dynamic testing through its accredited laboratory network.
Types of Shock Tests
Classical Shock Pulse Testing
Classical shock applies well-defined pulse shapes—half-sine, sawtooth (terminal peak), and trapezoidal—at specified peak acceleration and duration using programmable shock machines. MIL-STD-810 Method 516, IEC 60068-2-27, and JEDEC JESD22-B104 define classical shock requirements. Half-sine pulses are most common for general product qualification.
Drop Shock Testing
Free-fall drop testing (ASTM D5276, IEC 60068-2-31, ISTA protocols) simulates product drops during handling and transportation. Specimens are dropped from specified heights onto specified surfaces in controlled orientations. This is the most common shock test for consumer electronics, packaging, and portable devices.
Shock Response Spectrum (SRS) Testing
SRS testing synthesises complex transient waveforms that match a specified frequency-dependent response spectrum. It simulates pyrotechnic separation, launch vehicle staging, and complex field shock environments in accordance with MIL-STD-810 Method 517 and NASA-STD-7003 for the aerospace and defence industries.
Ballistic Shock
Ballistic shock testing simulates the high-frequency, high-amplitude transients from weapons firing, mine blasts, and explosive events. Testing uses specialised equipment capable of producing very high acceleration levels (>10,000 g) with short durations.
Seismic Shock Testing
Seismic qualification testing per IEEE 344 and ICC-ES AC156 simulates earthquake ground motion for electrical equipment, building-mounted systems, and critical infrastructure components in the construction and utility sectors.
Partnering with Infinita Lab for Optimal Results
Infinita Lab addresses the most frustrating pain points in the Shock Testing process: complexity, coordination, and confidentiality. Our platform is built for secure, simplified support, allowing engineering and R&D teams to focus on what matters most: innovation. From kickoff to final report, we orchestrate every detail—fast, seamlessly, and behind the scenes.
Looking for a trusted partner to achieve your research goals? Schedule a meeting with us, send us a request, or call us at (888) 878-3090 to learn more about our services and how we can support you. Request a Quote
Frequently Asked Questions (FAQs)
What are the main types of shock tests? Classical pulse (half-sine, sawtooth, trapezoidal), drop shock, SRS (shock response spectrum), ballistic shock, and seismic shock are the primary types, each simulating different real-world transient events.
What is the difference between classical shock and SRS testing? Classical shock uses simple, well-defined pulse shapes (half-sine, etc.). SRS testing uses complex synthesized waveforms that match a frequency-dependent severity specification, better representing real-world complex shock events.
What standards cover shock testing? MIL-STD-810 Method 516/517 (military), IEC 60068-2-27/29/31 (international), JEDEC JESD22-B104 (electronics), ASTM D5276 (drop), and IEEE 344 (seismic) cover the major shock test types.
What equipment performs shock testing? Programmable shock machines (mechanical, pneumatic, or hydraulic), free-fall drop testers, electrodynamic shakers with SRS synthesis capability, and resonant plate fixtures for pyro shock simulation perform different shock test types.
How are shock test levels specified? Classical shock specifies peak acceleration (g), pulse duration (ms), and pulse shape. SRS specifies the response-spectrum amplitude as a function of frequency. Drop tests specify height and orientation. All are derived from field measurements or standard profiles.
