Tech Library
Applications & Cases
[Application Note]
In recent years, wireless audio has become more commonplace and even the norm in many of our everyday products. The use of network audio, which does not use conventional media sources such as compact discs (CDs), is also expanding due to the increase in sound source data from high-resolution audio and subscription-based music distribution services. New audio usage is often centered on smartphone-based services that provide audio through the smartphone to speakers and earbuds [earphones, earpods, etc.] via Bluetooth connectivity. These two use cases for audio output have come to dominate.
The recent mass implementation of True Wireless Stereo (TWS) within earbuds, with their comfortable cable-free non-tangling fit, has yielded vastly improved sound quality over traditional Bluetooth audio technology. TWS also comes with the ability to cancel external noise (isolation) which results in quieter playback. This feature allows users to use TWS-based devices without concerns of the sound being “broadcasted” to surrounding areas.
Additionally, Bluetooth connected speakers, which also do not require cables for signal transmission, allow for unfettered placement of playback devices and speakers. These mobile speakers, with their built-in amplifiers, can operate on battery power and be completely portable.
Bluetooth enabled audio devices are easy to use, easy to connect to and have many advantages. However, since they require a wireless signal, they can be susceptible to problems that do not occur with cable-connected audio devices.
This article describes phenomena that can cause problems within Bluetooth audio designs and will provide examples of potential countermeasures.
In recent years, wireless audio has become more commonplace and even the norm in many of our everyday products. The use of network audio, which does not use conventional media sources such as compact discs (CDs), is also expanding due to the increase in sound source data from high-resolution audio and subscription-based music distribution services. New audio usage is often centered on smartphone-based services that provide audio through the smartphone to speakers and earbuds [earphones, earpods, etc.] via Bluetooth connectivity. These two use cases for audio output have come to dominate.
The recent mass implementation of True Wireless Stereo (TWS) within earbuds, with their comfortable cable-free non-tangling fit, has yielded vastly improved sound quality over traditional Bluetooth audio technology. TWS also comes with the ability to cancel external noise (isolation) which results in quieter playback. This feature allows users to use TWS-based devices without concerns of the sound being “broadcasted” to surrounding areas.
Additionally, Bluetooth connected speakers, which also do not require cables for signal transmission, allow for unfettered placement of playback devices and speakers. These mobile speakers, with their built-in amplifiers, can operate on battery power and be completely portable.
Bluetooth enabled audio devices are easy to use, easy to connect to and have many advantages. However, since they require a wireless signal, they can be susceptible to problems that do not occur with cable-connected audio devices.
This article describes phenomena that can cause problems within Bluetooth audio designs and will provide examples of potential countermeasures.
Applications & Cases
[Application Note]
TDK offers a full suite of sensors that are perfectly suited for drones of all types from consumer/prosumer models to industrial units.
 
In just a few years, drones have become indispensable in one application after another, including such diverse areas as agriculture, real estate and cinematography. For all this success, drones still have almost unlimited potential given their suitability for a wide variety of uses including delivery, inspection, search & rescue, monitoring, and mapping, to name just a few.
 
Fundamental to drone utility is sensor technology. Drones rely on diverse sets of sensors for two broad purposes. First for their own functionality, notably flight and navigation, and second, for their ancillary capabilities – cameras for vision, motion detectors to sense activity, heat sensors to detect temperature, and so on.
TDK offers a full suite of sensors that are perfectly suited for drones of all types from consumer/prosumer models to industrial units.
 
In just a few years, drones have become indispensable in one application after another, including such diverse areas as agriculture, real estate and cinematography. For all this success, drones still have almost unlimited potential given their suitability for a wide variety of uses including delivery, inspection, search & rescue, monitoring, and mapping, to name just a few.
 
Fundamental to drone utility is sensor technology. Drones rely on diverse sets of sensors for two broad purposes. First for their own functionality, notably flight and navigation, and second, for their ancillary capabilities – cameras for vision, motion detectors to sense activity, heat sensors to detect temperature, and so on.
Solution Guides
[Solution Guide]
One of the well-established key requirements in solar inverters is their high efficiency. But also, their costs, size and weight are subject to continuous improvements. One approach to better fulfil all these demanding requirements simultaneously is the use of multilevel topologies.
The main advantages of switching between multiple voltage levels are lower voltage stress for the semiconductors and lower ripple stress for the power chokes.
This means that lower-voltage semiconductors can be used, which are typically cheaper.
Lower ripple stress for the chokes makes smaller and thereby lighter and cheaper choke designs possible.
The flying capacitor topology is a multilevel topology, that is an interesting choice especially for (but not limited to) the booster stage of a solar inverter. As its name implies, it needs a capacitor as a key element. This article describes and compares possible TDK solutions therefor.
One of the well-established key requirements in solar inverters is their high efficiency. But also, their costs, size and weight are subject to continuous improvements. One approach to better fulfil all these demanding requirements simultaneously is the use of multilevel topologies.
The main advantages of switching between multiple voltage levels are lower voltage stress for the semiconductors and lower ripple stress for the power chokes.
This means that lower-voltage semiconductors can be used, which are typically cheaper.
Lower ripple stress for the chokes makes smaller and thereby lighter and cheaper choke designs possible.
The flying capacitor topology is a multilevel topology, that is an interesting choice especially for (but not limited to) the booster stage of a solar inverter. As its name implies, it needs a capacitor as a key element. This article describes and compares possible TDK solutions therefor.
Products & Technologies
Die TDK Corporation präsentiert mit den EPCOS Serien B72307S0* (StandarD S07 Compact Serie) und B72310S0* (StandarD S10 Compact Serie) noch kompaktere, bedrahtete Scheibenvaristoren. Die neuen Varistoren decken in der StandarD S07 Compact Serie ein breites Spannungsspektrum von 115 VRMS bis 460 VRMS, in der StandarD S10 Compact Serie von 130 VRMS bis 680 VRMS ab. Die maximale Beaufschlagung mit einem einmaligen Pulsstrom (8/20 µs) beträgt bei den StandarD S07 Compact Typen bis zu 1200 A, bei den StandarD S10 Compact Typen bis zu 2500 A. Bei Mehrfachbeaufschlagung liegt die Pulsstrombelastbarkeit nach UL 1449, 4th Edition, bei 500 A (StandarD S07 Compact) bzw. bei 1500 A (StandarD S10 Compact). Bis zu einer Umgebungstemperatur von 105 °C können die Varistoren ohne Derating betrieben werden.
Die TDK Corporation präsentiert mit den EPCOS Serien B72307S0* (StandarD S07 Compact Serie) und B72310S0* (StandarD S10 Compact Serie) noch kompaktere, bedrahtete Scheibenvaristoren. Die neuen Varistoren decken in der StandarD S07 Compact Serie ein breites Spannungsspektrum von 115 VRMS bis 460 VRMS, in der StandarD S10 Compact Serie von 130 VRMS bis 680 VRMS ab. Die maximale Beaufschlagung mit einem einmaligen Pulsstrom (8/20 µs) beträgt bei den StandarD S07 Compact Typen bis zu 1200 A, bei den StandarD S10 Compact Typen bis zu 2500 A. Bei Mehrfachbeaufschlagung liegt die Pulsstrombelastbarkeit nach UL 1449, 4th Edition, bei 500 A (StandarD S07 Compact) bzw. bei 1500 A (StandarD S10 Compact). Bis zu einer Umgebungstemperatur von 105 °C können die Varistoren ohne Derating betrieben werden.