Realizing that innovations in electronics can complement production innovations in gaining a competitive advantage, semiconductors are becoming increasingly important in the automotive value chain. Sensing is a major function of the electronics system, with position sensors as the biggest market segment in regards to automotive sensor demand. Magnetic position sensors in vehicles are increasingly installed for applications such as throttle valve position, suspension control, power assisted steering, electronic gas pedals, electronic brake pedals and adaptive headlight systems. In addition to previously mechanically-driven applications such as power steering, transmission actuation and engine cooling systems are also increasingly being electrically-powered, driving the demand for brushless DC motors and therefore stimulating the demand for motor position and control sensors in the automotive sector.
Realizing that innovations in electronics can complement production innovations in gaining a competitive advantage, semiconductors are becoming increasingly important in the automotive value chain. Sensing is a major function of the electronics system, with position sensors as the biggest market segment in regards to automotive sensor demand. Magnetic position sensors in vehicles are increasingly installed for applications such as throttle valve position, suspension control, power assisted steering, electronic gas pedals, electronic brake pedals and adaptive headlight systems. In addition to previously mechanically-driven applications such as power steering, transmission actuation and engine cooling systems are also increasingly being electrically-powered, driving the demand for brushless DC motors and therefore stimulating the demand for motor position and control sensors in the automotive sector.
Realizing that innovations in electronics can complement production innovations in gaining a competitive advantage, semiconductors are becoming increasingly important in the automotive value chain. Sensing is a major function of the electronics system, with position sensors as the biggest market segment in regards to automotive sensor demand. Magnetic position sensors in vehicles are increasingly installed for applications such as throttle valve position, suspension control, power assisted steering, electronic gas pedals, electronic brake pedals and adaptive headlight systems. In addition to previously mechanically-driven applications such as power steering, transmission actuation and engine cooling systems are also increasingly being electrically-powered, driving the demand for brushless DC motors and therefore stimulating the demand for motor position and control sensors in the automotive sector.
Electromagnetic Interference (EMI) has become a growing concern due to the increased electrification of automobiles, and particularly so with electric cars where large high current carrying wires run between the front and back of the vehicle. Magnetic position sensors with integrated stray field cancelation features provide high accuracy measurements even in the noisiest of EMI environments, commonly found in automotive applications.
Electromagnetic Interference (EMI) has become a growing concern due to the increased electrification of automobiles, and particularly so with electric cars where large high current carrying wires run between the front and back of the vehicle. Magnetic position sensors with integrated stray field cancelation features provide high accuracy measurements even in the noisiest of EMI environments, commonly found in automotive applications.
Electromagnetic Interference (EMI) has become a growing concern due to the increased electrification of automobiles, and particularly so with electric cars where large high current carrying wires run between the front and back of the vehicle. Magnetic position sensors with integrated stray field cancelation features provide high accuracy measurements even in the noisiest of EMI environments, commonly found in automotive applications.
For the first time, designers of high-speed electrical motors can use robust, compact magnetic position sensors, without the need to implement complex angle error compensation schemes in an external microcontroller or DSP to account for motor-shaft rotational rates. New magnetic position sensors with integrated Dynamic Angle Error Compensation (DAEC™) functionality deliver state-of the-art accuracy and increased signal performance by accounting for motor-shaft RPM speeds. In high-speed brushless DC (BLDC) motors the sensor’s high accuracy enables better execution of the commutation scheme, resulting in higher torque and efficiency, lower torque ripple and smoother operation.
The problem with the existing magnetic position sensors on the market is a delay which comes by nature with the signal processing. This led to wrong angle position outputs, especially at high rotation speeds. The value of the so called dynamic angle error depends on rotation speed. Additional hardware chips can calculate this error and do a software correction on the output angle. Therefore a huge software development is needed. But still this result is not as good as the DAEC™ from ams. The DAEC™ Dynamic Angle Error Compensation is the unique feature of the new generation of ams’ position sensors. It is a single chip solution which reduces the Dynamic Angle Error almost to zero. Of course it delivers all the advantages of contactless angle measurement and there is a much better accuracy over speed. By the way it is easy to use, simple to program and reduce development costs as well as time to market.
The problem with the existing magnetic position sensors on the market is a delay which comes by nature with the signal processing. This led to wrong angle position outputs, especially at high rotation speeds. The value of the so called dynamic angle error depends on rotation speed. Additional hardware chips can calculate this error and do a software correction on the output angle. Therefore a huge software development is needed. But still this result is not as good as the DAEC™ from ams. The DAEC™ Dynamic Angle Error Compensation is the unique feature of the new generation of ams’ position sensors. It is a single chip solution which reduces the Dynamic Angle Error almost to zero. Of course it delivers all the advantages of contactless angle measurement and there is a much better accuracy over speed. By the way it is easy to use, simple to program and reduce development costs as well as time to market.
The problem with the existing magnetic position sensors on the market is a delay which comes by nature with the signal processing. This led to wrong angle position outputs, especially at high rotation speeds. The value of the so called dynamic angle error depends on rotation speed. Additional hardware chips can calculate this error and do a software correction on the output angle. Therefore a huge software development is needed. But still this result is not as good as the DAEC™ from ams. The DAEC™ Dynamic Angle Error Compensation is the unique feature of the new generation of ams’ position sensors. It is a single chip solution which reduces the Dynamic Angle Error almost to zero. Of course it delivers all the advantages of contactless angle measurement and there is a much better accuracy over speed. By the way it is easy to use, simple to program and reduce development costs as well as time to market.
The problem with the existing magnetic position sensors on the market is a delay which comes by nature with the signal processing. This led to wrong angle position outputs, especially at high rotation speeds. The value of the so called dynamic angle error depends on rotation speed. Additional hardware chips can calculate this error and do a software correction on the output angle. Therefore a huge software development is needed. But still this result is not as good as the DAEC™ from ams. The DAEC™ Dynamic Angle Error Compensation is the unique feature of the new generation of ams’ position sensors. It is a single chip solution which reduces the Dynamic Angle Error almost to zero. Of course it delivers all the advantages of contactless angle measurement and there is a much better accuracy over speed. By the way it is easy to use, simple to program and reduce development costs as well as time to market.
Magnetic position sensors with new digital output interfaces deliver flexible and reliable communication standards for improved automobile safety and performance. For example, the SENT (Single Edge Nibble Transmission) interface realizes a cost-efficient alternative to an analog sensor in the system and a real digital transmission between sensor and ECU. Similarly, PSI5 (Peripheral Sensor Interface) is designed to meet the requirements of a universal, highly reliable automotive sensor interface at the lowest possible implementation costs.
A complete magnetic position sensor system produced as a System-in-Package (SiP) relieves the automotive supplier of the need to produce a PCB assembly when implementing magnetic position sensing.
A complete magnetic position sensor system produced as a System-in-Package (SiP) relieves the automotive supplier of the need to produce a PCB assembly when implementing magnetic position sensing.
为什么选系统级封装Addressing the automotive industry's demands for more electrical, mechanical and environmental robustness
• 因为Sip是一个模块封装的完整电路,它不太敏感于不正确的放置位置。.
• SiP适应完全被注塑封闭的外壳中,这个密封的装配可阻止液体的渗入,适合最恶劣的环境。
• 另外,SiP方便安装和定位。如SiP可沿二个轴弯曲,允许不同的定位
演示者
演示文稿备注
A complete magnetic position sensor system produced as a System-in-Package (SiP) relieves the automotive supplier of the need to produce a PCB assembly when implementing magnetic position sensing.
典型的SiP使用– 踏板位置传感Addressing the automotive industry's demands for more electrical, mechanical and environmental robustness
通常这是一个基于PCB的设计,PCB决定了外形和外壳的尺寸。
用SiP的产品设计更纤细和更高信价比,将所有必须元件整合进单个封装之中。
演示者
演示文稿备注
A complete magnetic position sensor system produced as a System-in-Package (SiP) relieves the automotive supplier of the need to produce a PCB assembly when implementing magnetic position sensing.
Magnetic position sensors fully compliant with the ISO 26262 standard (Automotive Safety Integrity Level), and developed in accordance with the SEooC (Safety Element out of Context) specifications support the integrated safety mechanisms and ASIL levels of any safety-critical application.