Accelerating Aerospace Innovations
The aerospace industry embodies humanity’s pursuit of progress beyond boundaries, linking earth to sky and orbit. From commercial flight to space exploration, it represents the constant drive to expand what is possible while demanding absolute confidence in every system.
Aerospace technologies enhance global connectivity, national security, and scientific exploration, while advancing technologies that influence everything from materials to electrification and autonomy. Three key platform types define engineering priorities:
- Civil Aviation – commercial airliners, business jets, cargo aircraft, and emerging eVTOLs.
- Defense Platforms – manned and unmanned military aircraft, rotary-wing systems, and air-defense assets.
- Space Platforms – launch vehicles, satellites, deep-space probes, and crewed spacecraft.
Trends & Drivers
The aerospace sector is rapidly transforming as programs push toward higher efficiency, lower emissions, and increased mission capability. This shift is redefining how engineers design, test, and validate critical systems.
- Electrification – Aircraft, VTOL, and spacecraft are adopting electric propulsion, advanced power electronics, and high-density batteries—driving demand for precise power, efficiency, and thermal testing.
- Certification Pressure – Strict standards (DO-160, MIL-STD-810, NASA GEVS) require robust environmental, thermal, electrical, and structural validation across all subsystems.
- Autonomy & Advanced Flight Control – More sensors, smarter control loops, and autonomous behaviors require high-resolution data capture to validate navigation, decision-making, and actuator performance.
- Multi-Domain Measurement Complexity – Modern platforms integrate electrical, mechanical, thermal, and optical systems, requiring synchronized, multi-domain measurements during both transient and long-duration events.
- Next-Generation Communications – Wired, optical, and RF networks support growing bandwidth and mission demands, driving advanced signal integrity and optical testing requirements.
Subsystems
While aerospace platforms differ widely by mission, their functionality is built on a common set of core subsystems. These subsystems form the technology stack within any aircraft or spacecraft, regardless of size, complexity, or operational environment. Every successful flight, launch, or mission depends on these underlying systems operating in coordination.
Viewing aerospace through this subsystem lens highlights shared design principles, integration challenges, and testing requirements. Each subsystem requires specialized validation methods and plays a distinct role in ensuring mission success.
Measuring efficiency with high precision: simultaneous measurement of input and output
Observation of Inverter Switching Waveforms
Using the OR trigger and Dual Capture, it is easy to trap and record failure conditions on electrical harnessses (wiring interconnects) over a long duration test.
Surge Waveform Recording & Power Monitoring
Measuring Conversion Efficiency of Power Conditioner
Evaluating Magnetic Components
Characteristics of Transient Response from Industrial Robots
Reference equipment for power calibration
How can I capture data from motion sensors synchronized with other analog data? The Yokogawa ScopeCorder series of instruments feature input modules and functions to make this possible.
Use built-in calculations to analyze motor rotor position of Brushless DC motors (BLDC) and Permanent Magnet Synchronous Machines (PMSM) and find the relative angle between the rotor and position sensors such as encoders or resolvers
Harmonic content is a key contributor to low power quality and agency standards are written to ensure manufacturers take action to measure and control harmonics.
RTCA Inc, (Radio Technical Commission for Aeronautics) Washington, DC, is a non-profit corporation that functions as a Federal Advisory Committee to the Federal Aviation Administration (FAA). Its recommendations serve as the basis for policy, program and regulatory decisions. Sub-committee SC-135 produces the RTCA/DO-160E document titled Environmental Conditions and Test Procedures for Airborne Equipment. This document defines the test conditions and procedures for testing airborne equipment and is the standard by which Boeing, Airbus and other manufacturers require avionic components and sub-systems to be tested.
In a new era where electrification, AI, robotics, and advanced communications are transforming industries and daily life, at the core of these breakthroughs lies test and measurement - the unseen discipline that ensures innovation is reliable, safe, and impactful.
How-tos
In this video we demonstrate the GPS data logging capability of the DL350 Portable ScopeCorder. Recording Position, Velocity, and Altitude simultaneously with accelerometers or other analog inputs is simple with the DL350's built-in features.
This video demonstrates how to measure transient phenomena on power signals using the Yokogawa Test&Measurement PX8000 Precision Power Scope.
In several applications, especially those testing AC power to a standard such as IEC61000-3-11, the voltage and current signals must be monitored to confirm there are no major dips and/or swells in the signal. This can be done with instruments capable of reporting rms values, including power analyzers, traditional oscilloscopes, and some data acquisition systems.
To test to a standard, however, the instrument must have an accuracy spec that is traceable back to a national standard of calibration such as ISO17025 or NIST.
Having multiple memory options allows engineering groups to optimize how data is stored, no matter if you need to record for a long time at slower sampling rates, do a fast capture at high sampling rates, or anything in between.
The Yokogawa Test&Measurement DL950 ScopeCorder operates as an oscilloscope and incorporates the ability to record data for long periods of time like a data acquisition recorder. There are four memory types on the DL950 ScopeCorder: internal memory, solid state drive, flash memory, and PC storage through the IS8000 Integrated Test and Measurement Software Platform. This videos talks about the advantages of each of these and how to pick the best data recording method for you.
Webinars
- Establishing baselines for system efficiency
- Conducting inverter control signal analysis at the systems level
- Identifying critical measurements for benchmarking inverter input, inverter output, and motor output
- Analyzing motor control signals, including torque control variables, positional sensors, and pulse-width modulation (PWM), as well as torque measurements
With ongoing innovations in motor and inverter technologies seeking to advance global decarbonization objectives in the automotive industry, it’s crucial that engineers have a thorough understanding of how to properly analyze these systems.
This complimentary webinar provides engineering professionals involved in motor and control system development with insights that enable data benchmarking and troubleshooting issues related to energy efficiency in electric vehicle (EV) powertrains.
Key webinar topics include:
