LabVIEW Powered Automation for EV Module Testing
                     LabVIEW-Powered Automation for EV Module Testing
Electric Vehicles (EVs) are driving the next major transformation in mobility. Beneath every 
efficient EV lies a network of electronic modules — from Battery Management Systems (BMS) 
and inverter boards to DC-DC converters, dashboards, and onboard chargers. Each of these 
modules must perform reliably under demanding electrical and environmental conditions, which 
makes robust testing an essential part of development.
Traditional manual testing methods are often slow, inconsistent, and labor-intensive, creating 
barriers to scale and repeatability. To overcome these challenges, LabVIEW-driven test 
automation is becoming increasingly the foundation of EV module validation, offering 
unmatched precision, consistency, and safety throughout the test cycle.
Why Automate EV Module Testing?
Automated testing transforms how validation teams operate by replacing manual variability with 
deterministic control. A LabVIEW-based test system offers clear advantages:
● Precision: Automates repeatable voltage, current, and temperature profiles with 
microsecond synchronization.
● Efficiency: Enables 24/7 endurance and stress testing without operator supervision.
● Safety: Integrates multi-layer hardware and software interlocks for operator and 
equipment protection.
● Data Integrity: Delivers high-speed, time-correlated data logging and analytics for full 
traceability.
For example, an automated LabVIEW test setup can execute a 48-hour continuous battery 
cycling test while simultaneously capturing waveforms, monitoring thermal behavior, and 
logging CAN data — a task nearly impossible to sustain manually.
👉 Discover how our LabVIEW Consulting Services enhance test efficiency.
Hardware Layer: Reliable Test & Measurement Foundation
A well-designed hardware layer forms the backbone of any successful EV module test bench. 
To emulate real-world operating conditions, the system typically integrates:
● Power Sources: Programmable DC supplies or Source Measure Units (SMUs).
● Electronic Loads: Emulate drivetrain or battery discharge conditions.
● DAQ & Switching Systems: PXI or CompactDAQ platforms for analog, digital, and 
thermal inputs.
● Communication Interfaces: NI-XNET for CAN, CAN FD, and LIN; NI-VISA SPCI for 
instrument control.
● Safety Circuits: Emergency interlocks, watchdogs, and door sensors for personnel 
protection.
This modular design allows for seamless expansion, whether adding new Device-Under-Test 
(DUT) channels, new sensors, or higher-power components, ensuring flexibility and future 
scalability.
👉 Explore our Test & Measurement Automation solutions.
Software Layer: LabVIEW as the Control Core
LabVIEW acts as the orchestration layer, unifying instrumentation, control logic, and data 
management. Its graphical programming and real-time control capabilities make it ideal for test 
automation in high-voltage EV environments.
Core Software Modules Include:
● Test Controller: Handles system boot, test sequencing, and controlled shutdowns.
● Sequencer Engine: Executes test scripts deterministically using QSM, Actor 
Framework, or DQMH architecture.
● Driver Layer: Employs NI-VISA, NI-DAQmx, and NI-XNET APIs for robust 
communication with test instruments.
● Safety Supervisor: Continuously monitors thresholds, interlocks, and relay states.
● Reporting Engine: Automatically generates test reports in PDF, Excel, or database 
formats, complete with plots and compliance metrics.
Together, these software elements ensure consistency, traceability, and smooth scalability 
across varying test scenarios.
Why This Architecture Excels
The combination of modular hardware and LabVIEW-based orchestration creates a flexible, 
repeatable, and safety-certified test ecosystem:
● Scalable: Expandable to new DUTs, sensors, or power levels without major redesigns.
● Repeatable: Deterministic sequencing guarantees identical test execution every time.
● Traceable: Centralized data and metadata enable complete audit trails.
● Safe: Multi-layer interlocks and continuous monitoring minimize risk.
This architecture supports diverse EV testing applications from high-current cycling and 
functional validation to long-duration reliability and thermal testing.
Beyond Electrical Testing: Machine Vision Integration
While electrical validation ensures performance, visual inspection confirms build integrity. 
Machine Vision Systems enhance overall quality assurance by detecting physical defects such
as solder bridges, connector misalignment, or missing components. When integrated with 
LabVIEW, vision inspection runs in parallel with electrical and thermal tests, forming a unified 
test platform that validates both functionality and workmanship.
👉 Learn more about our Machine Vision Systems for automated inspection.
Conclusion
LabVIEW offers a unified, modular, and industry-proven approach to EV module testing. By 
combining automated measurement systems, safety-driven software orchestration, and 
integrated vision inspection, engineers achieve faster validation cycles, improved data 
accuracy, and compliance-ready traceability.
At Unilogic Technologies, we bring over 14 years of NI-certified expertise in LabVIEW 
consulting, test automation, and machine vision. Our turnkey solutions help leading 
manufacturers across automotive, EV, pharmaceutical, and industrial sectors achieve higher 
reliability, reduced test time, and measurable ROI in every project.
👉 Read our EV Testing Case Studies