At Binary Palette, we specialize in delivering advanced engineering and IT solutions designed to meet the unique challenges of modern industries. From robust test and measurement systems to expert IT services, we provide scalable, reliable, and efficient solutions that empower businesses to succeed.

We specialize in integrating complex systems, particularly in test and measurement environments, and developing custom software solutions tailored to your needs.

Technologies & Expertise:

• Integration of complex systems in test and measurement environments
• Custom software development tailored to client needs
• Scalable and reliable system architectures
• Seamless integration using LabVIEW, VeriStand, and TestStand.
• Optimization of operational performance through automation and interoperability

Our expert software consulting services provide strategic guidance to optimize test and measurement systems. With our deep industry knowledge and experience, we ensure your projects are executed efficiently, delivering scalable, high-performance solutions that meet your specific needs.

We provide proactive system maintenance and engineering support to ensure the optimal performance of your test systems. Our services include:

• Routine system checks
• Troubleshooting and performance optimization
• Aligning your systems with industry standards
• Minimizing downtime
  With expertise in LabVIEW, VeriStand, and TestStand, we provide ongoing support for seamless operation and long-term efficiency.

Evaluate product performance, strength, and lifespan under various conditions.

• Quality Control: Inspect products on assembly lines for defects, flaws, and contaminants
• Non-contact Measurements: Inspect and measure delicate materials without damaging them.
• Barcode/QR Code Scanning: Automating product identification and tracking.
• Pattern Matching: Identifying inconsistencies and variations.

Measure the performance of products under specified environmental conditions to ensure that products perform as intended in real-world operating conditions. This can include:

• High and low extreme temperatures
• Temperature cycling
• High and low humidity
• Shock and vibrations
• High and low-pressure
• Pressure cycling
• Electromagnetic Interference

Test automotive braking performance by integrating:

Assess power generation & performance of a fuel cell by monitoring:

Evaluate the performance, reliability, and functionality of an Electronic Control Unit (ECU) to ensure that it performs as expected under various conditions, complies with safety and regulatory standards, and meets specifications.

• Check inputs, outputs, logic, algorithms, and communication protocols
• Simulate real-world operating conditions and stimuli
• Verify that the ECU meets specifications and standards
• Test for major error conditions
• Test the ECU's interaction with other systems

Battery Testing
• Battery Management Systems (BMS): Testing communication with the BMS through various conditions
• Charge Cycling: Monitoring battery performance with charge and discharge cycles and different environmental conditions like temperature and humidity.
• Shaker Testing: Mounting a battery on a shaker and monitoring its performance and communication while running it through a vibration road profile.

Inverter Testing: EV inverters are tested to ensure they are reliable, efficient, and safe before being integrated into an electric vehicle. Testing involves simulating operating conditions and fault scenarios, as well as performing safety tests.

Measuring the Acoustic properties of materials using various techniques:

Analyze the vibration patterns of a structure or component to evaluate its condition and identify defects...

Simulate real engine exhaust conditions in a laboratory by creating a controlled mixture of gases, including CO, CO2, H2, O2, NOx, hydrocarbons, etc., allowing researchers to test the performance of catalysts or other exhaust after-treatment systems under specific conditions. It is used in automotive applications to evaluate the emissions reduction capabilities of catalysts without needing a running engine on a vehicle.

This system uses electromechanical valves and mass flow controllers to create the desired mixture of gases and several gas analyzers to measure concentrations of all gases of interest. Automated furnaces and temperature controllers are used to heat the gas mixture to real-world conditions.