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EV Charging Infrastructure

Electric Vehicle Supply Equipment (EVSE), or more commonly charging stations, are a critical component in the migration from internal combustion. The availability (uptime & reliability) of stations and the speed at which they can charge are major factors in the adoption of EVs.

EVSE must also comply with key standards such as IEC 61851 and SAE J1772.

At the device, module and system levels, engineers are working to reduce charging times with higher charging voltages, while improving reliability and maintaining safety. Smart, flexible testing solutions enable designers to quickly troubleshoot and validate their designs.

EVSE Measurement Theory and Techniques

A block diagram of a DC fast charging station for electric vehicles​

Tracés des paramètres de puissance sur 100 acquisitions, notamment Vrms, Irms, puissance réelle, différence de phase, puissance apparente et puissance réactive.

En savoir plus :

Fiche d'analyse de l'entraînement du moteur par onduleur

EVSE technology

State-of-the-art DC fast-chargers convert 3-phase AC from the power grid to high-voltage DC. Systems are made up of:

  • Power factor correction and AC/DC converter
  • DC/DC converter
  • Control systems and power management
  • User interfaces
  • LAN / cellular communications
  • High voltage charging and communication vehicle port

Power Factor Correction (PFC) and AC/DC conversion

Chargers designed to connect to public utilities must limit the impact on the local grid or operators will be subjected to higher energy rates or penalties. Most utilities charge for power factor below 90 to 95% and many require compliance with harmonics standards.

The input stages of DC fast charging equipment are not only responsible for converting 3-phase AC to DC, but it must also ensure high power factor and low harmonic distortion, while maintaining high efficiency and reliability.

Oscilloscope-based systems with advanced power analysis software facilitate accurate, repeatable measurements, including:

A block diagram of a DC fast charging station for electric vehicles​

Tracés des paramètres de puissance sur 100 acquisitions, notamment Vrms, Irms, puissance réelle, différence de phase, puissance apparente et puissance réactive.

En savoir plus :

Fiche d'analyse de l'entraînement du moteur par onduleur

Oscilloscope display showing voltage, current and power loss in a MOSFET

Detailed switching loss measurements quantify loss in FETs and IGBTs within power conversion circuits. ​​

DC/DC converters and gate drivers

High power DC/DC converters provide isolation between the PFC block and voltage regulation for the vehicle charging port. High frequency transformers are often used for isolation and energy storage. New designs may use fast SiC MOSFETs to add efficiency and power density.

The fast switching speeds and voltage levels of SiC MOSFETS introduce measurement challenges due to high bandwidth and common mode voltages. Oscilloscopes with optically isolated probes and analysis software deliver accurate measurements even on high slew-rate, high common mode voltage signals. These include:

Control systems and power management

Embedded controllers are the brains behind the charging process. During charging they handle communication with the vehicle, regulate power flow, and monitor safety conditions. They also communicate with the user interface and digital networks.

These subsystems typically include processors or FPGAs, clocks, power rails, memory systems, and communications ICs, often operating on GHz signals with low amplitude. Since these systems operate in harsh physical and electrical environments, they require high noise immunity and power integrity.

Key measurements for validating and debugging these systems include:

Oscilloscope waveforms showing noise on power rails​

Ripple measurements quantify noise on power rails.

A Tesla (NACS) electric vehicle charging plug showing power connections, communications and protective earth.

EV interfaces use two or more large pins for power and protective earth. Smaller pins are used for communication and may include control pilot (CP), proximity pilot (PP) or controller area network (CAN).​

Vehicle Interface

Reliable communication between the charging station and vehicle battery management system is critical to manage the charging process and maintain safety.

Chargers that comply with IEC61851 incorporate a control pilot (CP) signal. The duty cycle of the CP signal conveys the maximum available current from the EVSE to the EV. This signal can be verified using an oscilloscope. Power line communications (PLC) may also be superimposed on this line for communication during the charging process. Some interfaces rely on serial data carried over CAN for communication between the EVSE and EV.

In both cases oscilloscopes are invaluable for checking signal quality throughout the system, looking for attenuation, noise and incorrect termination. Most Tektronix oscilloscopes can be outfitted with CAN bus decoding and triggering to display transactions synchronized with other system level activity.

In addition to conducting data communication, the charging interface must maintain current and voltage within specified limits. For example, the charger must limit the impact of line voltage transients, surges and sags on the DC output to the vehicle to specified levels and durations.

Key measurements include:

  • Communication signal integrity / noise
  • Duty cycle of the DP signal
  • System timing
  • Noise on DC output
  • Output regulation

User Interface and Network Communications

User interface devices often connect into the control system over standard serial buses such as RS-232, SPI or USB. Network communication provides key information for both charging station operators and users. Oscilloscopes and active probes are well-suited for signal and timing evaluation for user interface connections, LAN and wireless communications. Tektronix oscilloscopes support decoding on over 25 serial buses from RS-232 to wireless NFCs.

Key measurements include:

CAN serial bus decoded on an oscilloscope display​

CAN bus decoding may be used to display communications between the charging station and the electric vehicle.​​

EVSE Testing Reference Solution

This starting Configuration can be adjusted to suit your requirements.

Instrument/Probe/Option Quantity Description
MSO56B 1 5 Series B MSO with 6 input channels
Opt. 5-BW-500 1 500 MHz bandwidth
Opt. 5-SRAUTO 1 CAN, CAN-FD, LIN, FlexRay bus decoding and triggering
Opt. 5-PWR 1 Power measurement and analysis
Opt. 5-SV-RFVT 1 Spectrum view RF vs. time traces and triggers for EMI/EMC troubleshooting
TCP0030A 2 Two current probes
TMDP0200 or THDP0200 2 Two high voltage differential probes
TLP58 1 8-channel logic probe for protocol and mixed signal analysis
TPP0500B 1 Six passive voltage probes for voltage (included with oscilloscope)
Keithley DMM6500 1 6.5-digit multimeter for precision measurements

Frequently Asked Questions

Why is communication testing between EV and EVSE systems important?​

  • Enhanced User Experience: Effective communication testing ensures that electric vehicles (EVs) and charging stations can interact seamlessly, providing EV owners with a smooth and hassle-free charging experience. This is critical for user satisfaction and trust in the charging infrastructure.
  • Safety and Reliability: Communication testing helps detect and address potential safety issues and vulnerabilities in the charging system. By identifying and mitigating risks, it contributes to the overall safety and reliability of EV charging.
  • Interoperability: Interoperability testing ensures that different EV models and charging stations can communicate effectively. This is pivotal for creating an open and accessible EV charging ecosystem where users can choose from various charging options.
  • Standard Compliance: Many countries and regions have specific standards for communication protocols in EV charging. By adhering to these standards through testing, charging systems can meet regulatory requirements.

What are some common tests performed to verify power converters?​

  • Efficiency Testing: Power converters and PV inverters are tested for their efficiency, which assesses how effectively they convert electrical energy. High efficiency is essential for reducing energy waste and ensuring optimal system performance.
  • Safety Checks: Safety testing evaluates power blocks for potential risks such as overheating, short circuits, or electrical faults. Ensuring the safety of these components is crucial for preventing accidents and system failures.
  • Performance Validation: Performance testing assesses the power blocks' ability to operate under various conditions, including load variations and environmental factors. It helps ensure reliable and consistent performance.
  • Electromagnetic Compatibility (EMC) Testing: EMC testing checks whether power blocks emit electromagnetic interference and are immune to external interference. Compliance with EMC standards is vital for trouble-free operation in the presence of other electronic devices.
  • Temperature Profiling: Monitoring temperature is essential for preventing overheating, which can lead to component damage. Temperature profiling identifies potential thermal issues and helps maintain safe operation.

What are the typical measurements in the field of power electronics and EV systems?​

  • Voltage Measurements: Voltage measurements are essential for assessing the electrical potential within power electronics and EV systems. They provide insights into electrical circuits' behavior and ensure they operate within safe voltage limits.
  • Current Measurements: Current measurements gauge the flow of electric charge within power electronics and EV systems. Accurate current measurements are crucial for monitoring power consumption and ensuring electrical components' safety.
  • Temperature Monitoring: Temperature monitoring is vital for preventing overheating and ensuring the longevity of power electronics and battery systems in EVs. It helps maintain safe and efficient operation.
  • Power Factor (PF) Analysis: Power factor measurements assess the efficiency of electrical power conversion within power electronics. A high power factor indicates efficient energy use, reducing waste and energy costs.
  • Harmonics Analysis: Harmonics are unwanted distortions in electrical waveforms that can impact system performance. Harmonics analysis helps identify and mitigate these distortions to maintain power quality.
  • Efficiency Measurements: Efficiency measurements evaluate how effectively power is converted and utilized within power electronics and EV systems. High efficiency is essential for reducing energy waste and operating cost-effectively.
  • Voltage Ripple: Voltage ripple or fluctuations can affect the operation of sensitive electronics. Monitoring and minimizing ripples are important for ensuring stable and reliable system performance.
  • State of Charge (SoC) Measurements: SoC measurements are particularly relevant for battery management in EVs. They determine the available energy in the battery, allowing for accurate range estimations and preventing over-discharge.
  • DC Bus Voltage Measurements: Monitoring DC bus voltage ensures system stability and protects critical components, such as inverters and power converters. It is crucial for safe and reliable operation.
  • Energy Consumption Monitoring: Measuring energy consumption provides insights into how efficiently energy is used, allowing for optimization and cost savings in EV and power electronics applications. It helps in managing power usage efficiently and identifying areas for improvement.
  • Isolation Testing: Isolation testing ensures electrical safety and helps prevent electrical hazards. It confirms that circuits and components are properly isolated and free from potential faults, guaranteeing safe operation.


Serie 2 MDO Mixed-Domain-Oszilloskop

Oscilloscope à signaux mixtes portable MSO Série 2

Libérez de la place dans votre laboratoire sans compromis sur les performances en choisissant notre oscilloscope portable le plus compact. Avec seulement 38 mm d'épaisseur et moins de 1,8 kg, le MSO …
3 Series MDO Mixed Domain oscilloscope

Oscilloscope multidomaine MDO Série 3

Que vous testiez votre conception de bande de base pour l'IoT ou que vous cherchiez simplement à détecter des interférences électromagnétiques, l'oscilloscope MDO Série 3 est un incontournable. Contrairement aux autres oscilloscopes qui proposent une « analyse de spectre » par FFT avec traitement logiciel, l'oscilloscope Série 3 est équipé d'un véritable analyseur de spectre intégré offrant des performances de test RF et des spécifications RF garanties supérieures.

  • Options analyseur de spectre intégré jusqu'à 1 GHz ou 3 GHz
  • Le seul véritable analyseur de spectre intégré du marché des oscilloscopes
  • Bande passante de capture ultra large jusqu'à 3 GHz
4 Series MSO Mixed Signal oscilloscope

Oscilloscope à signaux mixtes MSO 4 série B

Le MSO 4 série B est un oscilloscope à signaux mixtes doté d'une bande passante pouvant atteindre 1,5 GHz, d'un écran tactile HD, de capacités de décodage série, d'entrées numériques et d'analyse de la puissance et des fréquences.

5 series B MSO - MSO58B

Oscilloscope à signaux mixtes MSO Série 5B

Le MSO de série 5 a un écran tactile, jusqu’à 8 entrées, des convertisseurs 12 bits analogiques-numériques et une bande passante. En savoir plus ici.

6 Series B MSO Mixed Signal oscilloscope

Oscilloscope à signaux mixtes MSO Série 6B

Dépannez et validez des conceptions haute vitesse grâce à la bande passante évolutive de 1 GHz à 10 GHz.

Keithley 6500 series

Électromètres haute résistance 6517B, 6514, et 6430

Nos instruments de mesure de courant et de charge les plus sensibles

Keithley DMM7510: Đồng Hồ Vạn Năng Lấy Mẫu Đồ Họa 7.5 Chữ Số

Keithley DMM7510 : multimètre d’échantillonnage graphique à 7,5 digits

  • Précision DCV de 0,0014 % (un an)
  • Numériseur 1 000 000 lectures/s
  • Écran tactile
2470 SMU front image for product series

SMU 2400 graphique à écran tactile de Keithley

  • Recherche sur les matériaux nanostructurés
  • Semi-conducteur de puissance GaN, SiC
  • Développement de biocapteurs
  • Conception de composants semi-conducteurs
  • Conception de capteurs pour l'automobile