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Intertek 70 Codman Hill Road
Boxborough, MA 01719
icenter@intertek.com 800-WORLDLAB www.intertek.com
The Ongoing Challenges in Automotive EMC Compliance
The Ongoing Challenges in Automotive EMC Compliance
http://intertek.com/automotive/emc-testing/ 1
Contents
Introduction ..............................................................................................2
History .......................................................................................................3
The Changing EMC Environment.............................................................3
Changing EMC Test Requirements ..........................................................6
Summary ...................................................................................................7
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Introduction
With advances in technology over the last decade, customer demand and OEM competition has forced automakers to try to integrate many of the latest technologies into their vehicles. Many of these technological advances, whether entertainment, communication or performance improvements, do succeed in bringing to the consumer a new level of comfort and convenience as well as enhanced safety features. But along with these features come new challenges to ensure EMC (Electromagnetic Compatibility) and device interoperability within the vehicle. EMC issues can result in minor annoyances such as unwanted noise through the entertainment system, as well as major issues such as loss of engine functions or control issues that could compromise the safety of drivers, passengers and the public. Add to this the growing demand of Hybrid Electric Vehicles (HEV) and Electric Vehicles (EV). These systems may bring a whole new set of concerns in relation to EMC. For these reasons, EMC is and will continue to be a very important topic of concern for the automakers’ present and future. There are two opposing forces at work influencing EMC in the vehicular environment. 1) The growing number of electronic components and modules for control, communications, and entertainment now being installed make achieving EMC far more demanding. 2) The force promising to bring the situation under control is the trend to replace complex vehicle wiring carrying analog, digital, and high-current signals with simpler, low-power signaling protocols. Between these two forces, engineers are modifying their predictive tools to keep up with changes at all levels – integrated circuit EMC evaluation, module EMC prediction and measurement, and whole vehicle characterization. As circuits operate at higher frequencies (and voltages), simulation methods have to adopt smaller grids for the accurate prediction of the resulting electromagnetic fields. As this process of modification is underway, the vehicle manufacturers need to assure that new modules have been tested to their respective EMC standards correctly and that the standards reflect the actual environment of future installation. While many vehicle EMC standards are non-governmental (and/or OEM specific) and therefore simpler to update, in the EU the Automotive EMC Directive 2004/104/EC contains its own requirements and is therefore more cumbersome to amend. Fortunately, it contains a number of international EMC standard references. With the recent surge of public awareness for a need for alternative vehicles such as EV’s and HEV’s , there are more independent auto manufacturers on the scene and they are starting to review their own EMC procedures and may see themselves developing their own standards based on their findings and business growth.
The Ongoing Challenges in Automotive EMC Compliance
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History
The popularization of the car radio in the late 1920s was the “canary in the coal mine” — the proverbial early warning— that automotive EMC would be an ongoing challenge. By the 1930s, a number of commercial radio brands were available. The early models were AM (amplitude modulation) only and very susceptible to both ignition noise and static buildup from the car’s tires. Both sources of disturbances were quickly overcome. Spark plug suppression was provided by resistive cables and resistive plugs; research on optimum spark plug suppression continued into the 1970s1. Conductive carbon was added to the car tires to prevent electrostatic charge buildup. In 1947, SAE J551, the first SAE (Society of Automotive Engineers) EMC standard, was published, but it was not until the proliferation of vehicular electronics in the 1970s that development of further vehicle EMC standards occurred.
The Changing EMC Environment
Today’s motor car contains an amalgam of legacy electrical/electronic functions and more recent devices – literally dozens of components or modules, sensors and actuators, and more than one network. Table 1 below lists typical functions and their attributes.
function history attributes
Airbag deployment Existing Critical
Braking control Existing Critical
Cabin environment Existing Comfort, Radio Noise, gage/warning function
Collision avoidance New Likely unlicensed radar 77 GHz.
Communications system
New Cellular, Bluetooth (800, 1900, 2400 GHz)
Emissions control Existing Environmental and legal concerns in some states
Engine ignition Existing Critical
Entertainment system New May include satellite radio receiver, FM modulator (low power 88-108 MHz).
Fuel injection Existing Critical
1“Relationship Between Spark Plugs and Engine-Radiated Electromagnetic Interference,” IEEE Transactions on Electromagnetic Compatibility, Burgett et. al.,August 1974, pp. 160-172.
The Ongoing Challenges in Automotive EMC Compliance
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Lighting system New Some Xenon discharge lamps.
Navigation system New GPS receiver
Noise cancellation New Comfort
Seat and pedal position Existing Critical
Security system Existing Short-range and Part 90 radio (170-300 MHz)
Stability control New Critical
Tire pressure monitoring
New Short-range radio
Transmission control Existing Critical
Table 1 Typical automotive electronic component or module functions.
Each of these functions exists in, and impacts, the vehicle’s EMC environment. For example, all of the control systems add to network/bus noise. Also, the communications, entertainment and security systems introduce radio sources while the GPS (global positioning systems) and satellite radio receivers require very low RF noise over their operating bands. Compounding these EMC challenges from the added electronic functions are the new factors associated with Hybrid Electric Vehicles (HEVs) and Electric Vehicles (EVs). Specifically, these include bus voltages exceeding 200 V, power inverter switching noise, and new bus/cable configurations. These issues are illustrated in the propulsion system block diagrams in Figure 1 and 2 for HEV and EV configurations.
The Ongoing Challenges in Automotive EMC Compliance
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Figure 1 Simplified HEV (Hybrid Electric Vehicle) block diagram.
Figure 2 Simplified EV (Electric Vehicle) block diagram.
In addition to the basics shown in these figures, there are the myriad modules, sensors, actuators, networks, and central control for the vehicle.
power
inverter
High
voltage battery
DC AC
DC/DC 12V battery
transmission
Electric motor Engine
12V battery
Power inverters and motors
High
voltage battery
Electronic
control unit
DC
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Changing EMC Test Requirements
Existing EMC whole vehicle and module test standards cover the range of electromagnetic phenomena in conventional vehicles2. Vehicle manufacturers have adopted SAE and international standards to varying degrees and have established their own EMC standards that the testing laboratory must follow closely. Table 2 summarizes some of the relevant standards by reference number.
A sample of automotive EMC standards
parameter SAE GM Ford Toyota Int’l
EMISSIONS
Radiated RF
CISPR
25
J551/1, J551/5
TSC7026G
TSC7058G CISPR 25
Conducted RF CISPR 25 TSC7058G CISPR 25
Conducted transient
J1113-42
GMW3097
ES-XW2T-1A278-AC
CS-2009.1 _ ISO7637-2
RADIATED IMMUNITY
RF immunity
J551/1, J551/12, J551/16, J1113/28
TSC7025G ISO 11452-2, ISO 11452-3
Magnetic field immunity
J551/17
J1113-22
GMW3097
ES-XW2T-1A278-AC
CS-2009.1 TSC7001G ISO 11452-8
COUPLED TRANSIENTS
Inductive coupled
transients
J1113-12
GMW3097
ES-XW2T-1A278-AC
CS-2009.1
TSC7001G
ISO 7637-2
CONDUCTED IMMUNITY
Susceptibility J551/13
J1113-2,3,4
TSC7315G ISO 11452-4
Transient J1113-11 TSC7001G ISO 7637-2,
ISO 7637-3
ESD J551/15
J1113-13
GMW3097
ES-XW2T-1A278-AC
CS-2009.1 TSC7018G ISO 10605
2 “An Overview of Automotive EMC Standards, “Poul Anderson, IEEE EMC Symposium 2006 Proceedings, 2006, pp. 812-816.
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Due to the high cost of performing whole-vehicle EMC testing and the need to expedite component integration, EMC testing is being performed at both the component or module and chip levels. The results are then used to predict compliance of the whole vehicle. Even without the added complexities of new HEV and EV propulsion systems, there are difficulties inherent in the existing test methods. At the chip or IC level, test standards such as IEC 61967-x family and SAE J145 2/3 do not fully predict installed EMC. The correlation between near- and far-field emissions may not hold, and the result is highly dependent on any external wiring harness. Also, at the module or component level, similar ambiguities exist. Component testing, however, can still be useful for identifying potential EMC problems. The introduction of HEV and EV propulsion systems clearly intensifies the challenges to existing test methods even more. High battery voltages reduce power transmission losses, but the resulting higher system impedances can render invalid emissions test results obtained with the artificial networks described in CISPR 253. Battery and drive motor impedance and impedance changes can also become an important factor in EMC. Worst-case RF emissions from vehicular power converters have been observed under transient conditions of load and speed4. Unfortunately, measurement standards have not yet taken this observation into account.
Summary
The automotive EMC environment is in a constant state of flux as new onboard electric devices, communications media (both wired and wireless), and new drive systems are added. Consequently, both EMC standards writers and vendors find themselves in a situation without fixed, agreed-upon testing procedures for assuring the compatibility of vehicles and components in hybrid and all electric cars. Ongoing change is the only constant. Automakers need to continue with strict attention to detail and try to model tests to capture the newer issues and concerns they come across. Component suppliers need to be aware of these concerns during their development cycles. Manufacturers of after market products and “cross over” devices, such as various kinds of IT equipment now being used in vehicles need to be cognizant of the requirements of the automotive EMC environments. Although automotive EMC standards are well-established by manufacturers and both domestic and international standards-making bodies, refinements may be
3 “High Voltage Automotive EMC Component Measurements Using an Artificial Network,” Nelson et. al.,IEEE Proceedings 18th Int. Zurich Symposium on EMC, 2007, pp. 195-200. 4 “HEV System EMC Investigation during Transient Operations,” Nelson and Aidam, IEEE Proceedings 18th Int. Zurich Symposium on EMC, 2007, pp. 205-208.
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needed to achieve better correlation between chip-level and component- or module-level measurements and whole vehicle testing. New HEV and EV drive systems continue to add further challenge to automotive EMC testing. About Intertek
As a leading provider of quality safety solutions serving a wide range of industries around the world, Intertek has the expertise, resources and global reach to support its customers through its network of more than 1,000 laboratories and offices – 39 specializing in EMC testing – in more than 100 countries around the world. For more information regarding Intertek’s new developments, call 1-800-WORLDLAB or visit: www.intertek.com
This publication is copyright Intertek and may not be reproduced or transmitted in any form in whole or in part without the prior written permission of Intertek. While due care has been taken during the preparation of this document, Intertek cannot be held responsible for the accuracy of the information herein or for any consequence arising from it. Clients are encouraged to seek Intertek’s current advice on their specific needs before acting upon any of the content.
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