Panasonic

The increasing requirement of performance of automotive devices leads to higher electric current flowing trough electric circuits. Also the number of ECUs mounted on vehicles is gradually increasing. As space inside vehicles is limited, ECU boards must be downsized. Therefore it is essential for electronic components mounted on such boards that they are able to pass large currents and also meet downsizing requirements. Unfortunately large current type inductors are usually designed with through hole mounting type with large product sizes, which are not suitable for downsizing. Furthermore, a large range of passive components such as resistors and capacitors are surface-mounted, but this process cannot be simultaneously performed with through hole mounting. Therefore two board mounting processes are required. To solve this issue for automotive customers, Panasonic developed a power inductor which can be surface mounted and is capable of passing currents as large as 87A.

3 Features of ETQP8M***J** & ETQPAM***JFW series:

• Industry’s smallest class of surface-mounted inductor capable of passing large currents
• The inductor enables ECUs to be directly mounted on engines by achieving excellent heat and vibration resistance.
• The environmental impact can be reduced through installation space saving

In contrast to conventional ferrite inductors, the magnetic metal composite material and the wired coil enable a gapless monolithic structure of the ETQP series. The result is a power inductor which has much lower heat generation due to reduced coil heat generation and increased coil heat dissipation. This way it was possible to enable large currents of 20A to 87A at a volume reduction of up to 50% compared to the ferrite type.

Heat resistance of 160°C is achieved by working on the composition of metal composite material. In addition, while the thick copper wire of the coil is drawn out to be used as terminals, an unique structure is adopted by fixing the terminals on the metal composite material body in a caulking structure on the bottom side, thus the vibration resistance is enhanced.

By adopting a metal composite suitable for downsizing, the company achieved a smaller inductor size with a similar performance for ferrite type inductors, which makes it possible to reducing the installation area, reduce the size of equipment, and reduce the number of materials used. It is possible to reduce the environmental load.

Unique terminal structure technology to assure heat capacity as SMD type, with the copper wire of the coil drawn out to be used as terminals.

Fore more information, visit: Automotive power inductors | Panasonic Industry Europe GmbH

180°C specified – What does it really mean?

Panasonic Power Inductors are specifically designed for harsh environmental conditions in engine,  transmission, braking systems and powertrain applications. The target was from the beginning to develop a product that is very resistant to vibration and temperature. The result was the ETQP Series, which achieved this goal and set a new quality standard for automotive metal composite power inductors. As for vibration resistance we already gave deeper insights, this time we want to focus on temperature resistance of the Panasonic ETQP Series. As there is an increased number of applications which require a maximum temperature resistance of 180°C, there are also Power Inductors introduced to the market which state a temperature resistance of up to 180°C. But what does actually stand behind such a specification with the unclear definition of up to?

ETQP Power inductor design

To understand the impact of temperature on a power inductor we first want to take a look at the components and materials which the ETQP series is made up. The core consists of metal composite powder which is bound by a proprietary heat resistant binder system. The metal core material has a curie temperature of over 500°C, the core binder material has a heat resistance of over 200°C. The wire wound coil inside which is placed inside the core has a high quality amide imide wire coating material which is heat resistant over 200°C. All components were deliberately chosen with highest quality available in the market.

Specified temperatures

After the detailed explanation of the temperature robustness of each single component we can take a look at the temperatures of the standard endurance specification. The table below shows the specified temperature resistance of 150°C, 155°C and 160°C for a duration of 2000 hours, depending on the series.

But that does not automatically mean that the power inductor is being destroyed when the specified temperature is exceeded. In fact each ETQP Power Inductor can handle even 180°C for a certain period of the specified lifetime. But this extraordinary temperature stress has an negative impact on the total lifetime which can be guaranteed for the product. This impact can be calculated by the Arrhenius formula and life time temperature profile, which we want to take a deeper look at now.

Lifetime vs Temperature

The following graph shows the relationship between lifetime and temperature stress of an ETQP inductor which has a specified temperature of 150°C. It shows an example of an application profile which exceeds the specified temperature by 30°C for 10 hours of its lifetime. The impact can be calculated with help of the Arrhenius formula. In case of this scenario, the guaranteed product lifetime of 2000 hours is being reduced to only 1750 hours at 150°C plus 10 hours at maximum 180°C. Than it has to be looked into the required overall lifetime of the power inductor to evaluate if the remaining lifetime still matches the requirements of the application.

Conclusion

As with many other data in the specification sheet of a power inductor, there has to be a deeper look behind what is presented at first sight. Even if a temperature resistance of 180°C is declared, it is not clear for how long the product can resist this temperature and what is the impact on the overall lifetime of the component. Panasonic intentionally does not state a temperature resistance of up to 180°C of the ETQP Series, as this information would be misleading without a deeper look into the overall temperature profile of the target application. However due to the high quality materials and design of the product, it definitely can be used for applications which require a temperature resistance of up to 180°C for a limited period of time. The product engineers from Panasonic will be happy to help you with detailed information and guidance  if you need support in such a case.

To learn more, please visit our website:

Automotive power inductors | Panasonic Industry Europe GmbH

Admittedly, Wi-Fi technology is not the latest thing – but it’s still state of the art when it comes to processing higher data rates, especially in personal area networks.

Now, Panasonic Industry is breaking new ground with its new PAN9520 wireless module. Containing the ESP32-S2 chip, it can be considered as the first Espressif-based module that enables standalone Wi-Fi applications.

The PAN9520 is part of a new generation of Panasonic Industry’s evolution boards coming with the Arduino form factor, serving the trend for mass-market available shields with the mere purpose of rapid prototyping.

Surveillance cameras, for instance, still are a domain of Wi-Fi networks, so let’s look exemplarily at the Arduino PAN9520 evaluation board and its interaction with the OV2640 camera – from the required hardware and toolchain to finally running the demo. So join us for this step by step instruction:

1. Some specs at first

2. Required Hardware

Figure 1. The Panasonic Industry PAN9520 is a 2.4 GHz 802.11 b/g/n embedded Wi‑Fi module based on Espressif ESP32-S2 that includes the powerful Xtensa 32-bit LX7 CPU.

Figure 2. OV2640 Camera Module with flexible PCB connector (like this one)

3. Installing Toolchain

The project has been developed in Visual Studio Code (VS Code). Thanks to its cross-platform compatibility, the code can be built and adapted on all operating systems.
You are required to take two simple steps:

1. Install Visual Studio Code (here)

2. Install PlatformIO Extension over the VS-Code extension menu and wait for the installation to finish, this might take a while.

3. Restart Visual Studio Code and clone the project either by typing in the Terminal:

git clone –recursive https://github.com/panasonic-industry-europe/pan9520-etu-camera-stream-web-server.git

Or by going directly to the GitHub repository https://github.com/panasonic-industry-europe/pan9520-etu-camera-stream-web-server.git and download the Code directly from there.

4. Go to "File" -> "Open Folder" and select the project folder containing this application. Wait for all the dependencies to be downloaded and installed automatically.

4. Editing the Code

Basically, the code works out of the box. However, it is important to know where to change the settings for the softAP, e.g. to change the password or the SSID.

main.c

In the main.c file, the initialize_cam function is used to configure and initialize the hardware to ensure that the camera works properly (lines 38-61). These settings were made for the OV2640. In principle, it is possible to connect other cameras if the pinout is similar. In the main function app_main, the previously mentioned initialization of the camera is started alongside the WiFi access point and the webserver.

httpd.c

In the httpd.c file the settings are configured for the webserver. The setup for the webserver is done in the app_httpd_main function, where two URI handlers are being registered: the index_handler for the static Html output and the stream_handler which streams the camera image continuously.

What you end up seeing in the browser is set in the index_handler (line 45-73). A simple static text "PAN9520 ETU Cam live stream" (line 60) alongside the continuous camera stream in a small box below the text (line 61) which is being delivered by the stream_handler (line 76-139). If you analyze the code more closely, it becomes clear that the image is loaded from the framebuffer (line95-100) continuously and sent in fragments so-called chunks (line 101-127). A calculation of the framerate is displayed in the logging (line 128-137).

Wifi.c

The settings of the WiFi connection are made in the wifi.c file. The Access Point configuration like the SSID name or maximum numbers of connections is set in lines 30-34. The event handling for Wifi is handled in the wifi_event_handler function (line 39-58), for the sake of simplicity, this function will not be discussed further in detail. It is only important to know that there are basically two states from the handler's point of view: that of a connected and disconnected client.

The most important settings and initializations of the access point are made in the wifi_init_softap function (line 61-83). The SoftAp is assigned a static IP address (line 66, in this case 192.168.4.1) and a password in line 75. WPA2 is being used as a security certification program (line 78), but it’s also possible to change this. However, this requires changing the security features in menuconfig. (see here)

5. Get things connected

The PAN9520 ETU contains a 24-pin FPC connector for operating a camera module via an 8-bit parallel camera interface and SCCB (Serial Camera Control Bus). Connect the camera like shown in the picture. Please make sure that the lens is turned towards you so that the pinning is the right way round. As soon as the camera and Evaluation Board are connected, plug in a micro USB cable in the “USB Module” Interface.

6. Flashing and Running the Demo

1. Open VS Code
2. Click on the project task menu (Alien Head) and choose: esp32-s2-kaluga-1
3. Click on General and then Build.
4. Press reset while holding pressed down the SW1 Button. This will activate the download mode.
5. Click on General and then Upload.

After the upload, you will see an error message in the terminal. This is because the task can’t reset the Board itself. You have to reset the board by pressing the reset button.

1. 1. A Wi-Fi Access Point will occur with the SSID you named above
   2. Connect to that AP with the password you set
   3. After the connection has been established open a browser and type 192.168.4.1 into the URL field
   4. Enjoy the livestream!

Far more than constructive or material differences, it is the principle – or more specifically: the pattern – of laser trimming that makes the difference for a SMD chip resistor’s reliability and performance. Let us investigate, why:

Resistors - seemingly the most accessible of components in almost any application. However, the process of manufacturing surface mount chip resistors is rather complex. In a typical construction of a surface mount chip resistor, there is a block of alumina substrate, which could be manufactured from several kinds of ceramics. Then, there are the electrodes which conventionally have several layers including nickel and tin. The resistive element is printed on the ceramic substrate - and then trimmed using a laser. It is the laser trimming that ultimately defines the resistance value of the final chip resistor.

The laser trimming is a deciding factor in the quality and performance of the end product. There are several factors that play a decisive role here: The laser trimming must be stable in the long run and should not deteriorate. Taking almost any application into account, resistors go through thousands of cycles in their lifetime and the resistance value is expected to remain constant. Additionally, the laser trimming should be of utmost accuracy, so that the desired resistance value can be achieved within the range of the defined tolerance. Furthermore, the trimming speed itself is important while not “sacrificing” the performance of the resistor. In component manufacturing, there is usually a trade-off between speed and accuracy. Panasonic Industry factories pursue the highest efficiency and speed in manufacturing; however, it is always made sure that the quality of the products does not drop because of this. Last but not least, trimming geometry is the most crucial aspect of all. This geometry defines other characteristics of the resistor like power range and pulse withstanding capabilities.

The trimming pattern can have several shapes and geometries – in the following overview we’ll have a deeper look at two (important ones!) of them:

L-pattern:

The L-pattern is a fast and well-known trimming pattern. This pattern includes two parts: the first part marked with 1 in image 1 defines the resistance value slightly below the targeted resistance value, while the second part marked with 2 accurately corrects and adjusts the resistance value within the allowed tolerance range. Analyses in the Panasonic Industry technical laboratories illustrate, however, for certain features like pulse-withstanding characteristics, this trimming method is not ideal, because, with the occurrence of pulse, certain areas around the trimming are exposed to higher temperatures and hot spots, see image 3. This is why this laser pattern is mostly used in the more conventional resistors, in which pulse withstanding characteristics are not that essential. The L-pattern is otherwise very fast and easier to apply.

Figure 1. The L pattern

Symmetrical C-pattern:

Panasonic Industry’s solution for producing premium resistors with pulse withstanding capabilities is the symmetrical C pattern. As opposed to the L- pattern, where the pulse load and heat would concentrate on the corner and edge of the pattern and, in this pattern, the trimming shape is changed to an arc, similar to the letter C. The current pathway here is bi-directional, so two symmetrical trimming patterns are used, see image 2. Based on the Panasonic load and heat simulation study, the heat concentration is reduced by 64% using our unique technology. This enables the resistor to have a higher power range and better pulse characteristics.

Figure 2. The symmetrical C pattern

However, the C geometry is far more complex to realize with the laser, because it is much slower and has to be monitored meticulously to maintain the desired resistance value. But for applications requiring pulse-resisting chip resistors, the Symmetrical C-pattern would be a perfect solution.

Figure 3. Comparison of hot spot buildup using L pattern and symmetrical C pattern

Panasonic Industry is constantly seeking state-of-the-art solutions to further improve its resistor portfolio. The highly-trained engineering team at the Morita factory in Fukui, Japan, is continuously researching and testing new materials and methods to enhance the quality and reliability of the resistors.

The relevance of smart metering has increased globally during the last couple of years for different applications such as water, gas and electricity – on both the supplier and the consumer side.

Additionally, the global shipment of smart meters has reached approximately 136.45 million units in 2020, according to the Global Smart Meters Market report - and is even assumed to reach 198.53 million units by 2026, forecasting a CAGR of 6.6% from 2021 to 2026.

In most countries, it has become common sense to tackle the environmental effects caused by pollution and to strive for adopting emission control regulations. Smart grids are a promising approach in this regard – and essential in the course of this: smart meters.

Some basics: Smart meters are digital meters representing a transformative technology for the utility industry and its customers. They enable two-way communication between the meter and the supplier.

Typically, their circuit diagram is as displayed below:

There are three main areas of a smart meter design, namely the power system, the microcontroller, and the communications interface. The power system has a switched-mode power supply and battery backup to ensure that the metering electronics remain powered even when the mainline is disabled. A Microcontroller Unit (MCU) includes an Analog-to-Digital Converter (ADC) and Digital-to-Analog Converter (DAC) to provide intelligence. And the communication interface allows the meter to interact with the rest of the grid - and in some cases the end user’s network.

Given this brief overview of basic smart meter technology, let’s take a brief trip through the world of passive components and investigate which capacitors, resistors and inductors optimally suit the needs of smart metering applications and why.

Capacitors

At the input side of the power supply circuit, film capacitors are commonly placed in EMI filters for EMI suppression purposes. In order to protect users from harm due to electric shock, X/Y classified EMI suppression film capacitors are normally required with high voltage impulse handling ability.

Taking these requirements into consideration, Panasonic Industry provides an excellent metallized PP film capacitor solution with ECQUA (safety class X2) and ECQUB (safety class X1/Y2) series for high safety and high reliability.

Thanks to Panasonic’s in-house patterned metallization technology (also known as “fuse function”), ECQUA series and ECQUB series (fuse function applies to class X1 only) offer overvoltage impact reduction and therefore guarantee high safety with open failure mode.

To ensure smart meter reliability also for outdoor metering products - especially under humidity exposure - Panasonic Industry developed its enclosure sealing technology and aluminium vapor deposition to achieve a high humidity resistance.

For smoothing in the input side, typically Tantalum capacitors are employed in parallel since they have a high capacitance level. But they suffer from derating, so for a 12V line, usually 25V caps are used.

To overcome that voltage derating, Panasonic Industry offers Polymer capacitor technology to efficiently replace those tantalums. Polymer caps provide high capacitance values at a very low ESR – in this case, for a 12V line, one 16V POSCAP or OSCON would be the product of choice, combined with reliable performance in a miniaturized housing.

Replacing two Tantalums in parallel with one Polymer capacitor – have a look at the following overview.

1.xV dc/dc Input (Smoothing)

Coming to the 3rd main area of a smart meter, the communications interface, amplifier (DSL) circuit is especially important for amplifying the small signals from sensors which are later converted into digital signals that MCU can process. Panasonic Industry provides its stacked metallized film chip-type capacitors to improve the filtering ability in the amplifier circuit.

The stacked metallized PPS film capacitor ECHU(X) series feature stable capacitance characteristics against temperature, frequency and DC bias – next to a very compact size (down to 0603). And there is no need for concerns about piezoelectric effects as known from MLCCs. With its high preciseness for high-speed data transmission, ECHU(X) series is the ideal solution to optimize the design for DSL circuits.

Simplified DSL circuit for smart meter

Resistors

Similar to capacitors, resistors can also be used for different purposes in smart meters.

For the motor control of the valve system, it is essential to use resistors with high precision, high reliability, and high stability specs over the entire lifetime of the meter - which is of course meant to be a long one.

Additionally, in the current-voltage sensor, the output signal is highly dependent on the level of accuracy of the resistors employed. Meeting those requirements, Panasonic Industry offers a wide range of high precision resistors in thin-film (ERA* series) and thick film (ERJPB series) technology.

Looking at the DC-DC converter, it is common to use resistors with a higher voltage range and pulse-withstanding capabilities. The wide variety of Panasonic anti-pulse resistors (ERJP/T series) makes it easy to find the perfect component for each and every design.

Occasionally, smart meters are exposed to areas or conditions with tougher environments. Standard resistors sulfurize when getting in contact with above-average concentrations of oil in the air. For this, anti-sulfur resistors come into play, coming with silver or gold layers in the inner terminals to avoid sulfurization.

Panasonic’s anti-sulfur portfolio offers two major product categories, one using silver and one using gold, each in a variety of sizes and resistance values.

Circuit protection

In the power supply line, it is crucial to protect the IC from an overcurrent that might even cause a fire. Panasonic Industry chip fuses render an appropriate solution for making sure that the IC - and in the end the entire smart meter - remains safe. Furthermore, for the communication line, no matter if it is cellular RF or Wi-Fi, the signal has to be protected against ESD and noise. The signal processing, however, has to happen with the minimum of signal degrading. Panasonic ESD suppressors can withstand a high amount of ESD with minimum degrading of the signal and minimum insertion loss (S21) of 0.4 pF.

Inductors

Next to capacitors, the DC/DC input requires also an inductance for current smoothing.

An established technology would be THT wire-wound inductors with a ferrite core. They, however, require considerable space as well as two reflow processes for mounting on the PCB.

Here, Panasonic Industry offers a more elegant solution with the ETQP_L and ETQP_M series, which both provide a much higher energy density that leads to a remarkably higher efficiency due to their innovative metal composite technology.

Therefore, both series only require half the space on the PCB compared to the conventional THT wire-wound inductor. Thanks to SMD mounting, only one reflow process is needed – which of course saves further production time and costs. The images below show an example of the possible differences on a PCB.

1.xV dc/dc Input (Smoothing)

Summary

The high expectations regarding compact housings, high performance and lifetime: Next-gen smart metering applications meet them, if the used components are the right ones. Manufacturers like Panasonic Industry offer the entire range of passive components, dedicated to the reliability and functionality of tomorrows smart metering innovations.

Undoubtedly, downsizing is a trend in the electronics industry - watch this latest and comprehensive short video and learn what Panasonic Industry has to offer for resistor downsizing - while ensuring the highest power range in smallest case sizes and avoiding the risk of solder joint cracks.

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Find more information on resistors by Panasonic Industry Europe here.

In plastic materials that are flame retardant with red phosphorous, outgassing can occur.

This has an impact on electronic components – in relays, for example, it can cause increased contact resistance, and some corrosion phenomena of components on printed circuit board assemblies (PCBAs) can also be traced back to red phosphorous.

In both the outgassing itself and the corrosion process, humidity plays a crucial role. In certain environmental conditions, it leads to the formation of different phosphorous acids and gaseous phosphine.

Now, there is a whitepaper available, comprehensively addressing the phenomenon and discussing ways to tackle it.

On the occcasion of its presentation during the latest International Conference on Electrical Contacts (ICEC), Panasonic Industry's most specialized experts spoke about the influence of plastics containing red phosphorous on electronic components and relays and shared their research of the influence of three differently flame-retarded polyamide (PA) choke coil bobbins on the contact resistances of a nearby unsealed relay.

This illustrated fundamental component design-in insights to overcome contact failures and increase the reliability and lifetime of applications using relays.

For anyone interested in learning more details about this topic, a comprehensive whitepaper from Panasonic's researchers is available free of charge here.

Did you know that not all film capacitors are big fellows with two or four legs as you would commonly guess? And also, that besides the well-known PP and PET dielectric there are

film capacitors using PPS or PEN as a dielectric material?

"The bigger, the better" is no longer necessarily true - and all the more so since

electronics design is evolving continuously. Also miniaturized housings can conceal great amounts of power. 

High precision, high performance – and contemporarily miniaturized: An ideal choice for

optimizing countless electronic circuit designs.

A higher level of power in smaller parts – this is undoubtedly the overriding direction where the electronic component market is currently heading.

That also applies for resistors, being the smallest and most accessible components in any electronic design. When looking, for instance, at a standard resistor in 1206 case size with a power range of 0.25W, there is a constant demand from the market to achieve this range in a case size not larger than 0603.