Портативная электроника

The ADP5350, a power management IC (PMIC), combines one high performance buck regulator for single Li-Ion/Li-Ion polymer battery charging, a fuel gauge, a highly programmable boost regulator for LED backlight illumination, and three 150 mA LDO regulators.

The ADP5350 operates in trickle charge mode and in constant current (CC) and constant voltage (CV) fast charge mode. It features an internal field effect transistor (FET) that permits battery isolation on the system power side.

The ADP5350 fuel gauge is a space-saving and low current consuming solution. It is optimal for rechargeable Li-Ion battery-powered devices, and features a voltage-based, battery SOC measurement function.

The ADP5350 boost regulator operates at a 1.5 MHz switching frequency. It can be operated as a constant voltage regulator or as a supplemental constant current regulator for multiple LED backlight drivers.

The ADP5350 LED drivers can support a wide range of LED backlight configurations, either multiple LEDs in parallel or in series.

The ADP5350 low dropout (LDO) regulators are optimized to operate at low shutdown current and quiescent current to extend battery life. The device also operates as a load switch that can be fully turned off or on.

The I²C-compatible interface enables the programmability of all parameters, including status bit readback for operation monitoring and safety control.

The ADP5350 operates over the −40°C to +125°C junction temperature range and is available in a 32-lead, 5 mm × 5 mm LFCSP package and a 32-ball, 3 mm × 3 mm WLCSP package.

Applications

• Rechargeable Li-Ion and Li-Ion polymer battery-powered devices
• Portable consumer devices
• Portable medical devices
• Portable instrumentation devices
• Wearable devices

The ADA4622-1/ADA4622-2/ADA4622-4 are the next generation of the AD820/AD822/AD824 single-supply, rail-to-rail output (RRO), precision junction field effect transistors (JFET) input op amps. The ADA4622-1/ADA4622-2/ADA4622-4 include many improvements that make them desirable as upgrades without compromising the flexibility and ease of use that makes the AD820/AD822/AD824 useful for a wide variety of applications.

The input voltage range includes the negative supply and the output swings rail-to-rail. Input EMI filters increase the signal robustness in the face of closely located switching noise sources.

The speed, in terms of bandwidth and slew rate, increases along with a strong output drive to improve settling time performance and enables the devices to drive the inputs of modern single-ended,successive approximation register (SAR) analog-to-digital converters (ADCs).

Voltage noise is reduced; although the supply current remains the same as the AD820/AD822/AD824, broadband noise is reduced by 25%, and 1/f is reduced by half. DC precision in the ADA4622-1/ADA4622-2/ADA4622-4 improved from the AD820/AD822/AD824 with half the offset and a maximum thermal drift specification added to the ADA4622-1/ADA4622-2/ADA4622-4. The common-mode rejection ratio (CMRR) is improved from the AD820/AD822/AD824 to make the ADA4622-1/ADA4622-2/ADA4622-4 more suitable when used in noninverting gain and difference amplifier configurations.

The ADA4622-1/ADA4622-2/ADA4622-4 are specified for operation over the extended industrial temperature range of −40°C to +125°C, and operate from 5 V to 30 V, with specifications at +5 V, ±5 V, and ±15 V. The ADA4622-1 is available in a 5-lead SOT-23 package and an 8-lead LFCSP package. The ADA4622-2 is available in an 8-lead SOIC_N package, an 8-lead MSOP package, and an 8-lead LFCSP package. The ADA4622-4 is available in a 14-lead SOIC_N and a 16-lead, 4 × 4 mm LFCSP.

Applications

• High output impedance sensor interfaces
• Photodiode sensor interfaces
• Transimpedance amplifiers
• ADC drivers
• Precision filters and signal conditioning

ADA4622-1/ADA4622-2 представляют собой следующее поколение прецизионных операционных усилителей на полевых транзисторах с управляющим переходом (JFET) AD820 и AD822, поддерживающих работу с однополярным питанием и имеющих rail-to-rail диапазон выходных напряжений (размах напряжения ограничен напряжениями питания). Схема ADA4622-1/ADA4622-2 содержит множество улучшений, что делает его предпочтительным выбором для модернизации существующих проектов без принесения в жертву широких возможностей конфигурирования и простоты применения, которые делают AD820 и AD822 привлекательным для широкого спектра областей применения.

Диапазон входных напряжений включает в себя отрицательное напряжение питания, а размах выходного напряжения ограничен напряжениями питания. Для повышения устойчивости при воздействии близкорасположенных импульсных источников шума в компонент добавлены входные фильтры электромагнитных помех.

Он имеет возросшее быстродействие (ширина полосы и скорость изменения фронтов), а также больший уровень выходного сигнала, что обеспечивает улучшение показателей времени установления и позволяет использовать усилитель в качестве входного интерфейса современных аналого-цифровых преобразователей (ЦАП) последовательного приближения (SAR) с несимметричным входом.

Уровень напряжения шума уменьшен по сравнению с AD820 и AD822: широкополосный шум меньше на 25%, а шум 1/f меньше в два раза при том же значении потребляемого тока. Статические характеристики ADA4622-1/ADA4622-2 также лучше: напряжение смещения уменьшено в два раза, а кроме того в спецификации ADA4622-1/ADA4622-2 добавлено значение максимального температурного дрейфа. И, наконец, ADA4622-1/ADA4622-2 обладают лучшим по сравнению с AD820 и AD822 значением коэффициента ослабления синфазной составляющей (CMRR), что делает данный усилитель более подходящим для использования в неинвертирующей конфигурации и конфигурации усилителя разностного сигнала.

ADA4622-1/ADA4622-2 гарантированно работают в расширенном промышленном температурном диапазоне от −40°C до +125°C. Рабочий диапазон напряжений составляет от 5 В до 30 В, а спецификации в техническом описании даны для напряжений +5 В, ±5 В и ±15 В. ADA4622-1 доступен в 5-выводных корпусах SOT-23 и 8-выводных корпусах LFCSP. ADA4622-2 доступен в 8-выводных корпусах SOIC, 8-выводных корпусах MSOP и 8-выводных корпусах LFCSP.

Области применения

• Интерфейс с датчиками, имеющими высокий выходной импеданс
• Интерфейс с датчиками на базе фотодиодов
• Трансимпедансные усилители
• Драйверы АЦП
• Прецизионные фильтры и схемы аналогового преобразования сигналов

The circuit shown in Figure 1 is an ultralow power, multichannel data acquisition system that can be powered by a photovoltaic (PV) cell or thermoelectric generator (TEG). The circuit uses the industry’s lowest power, multichannel, 12-bit successive approximation analog-to-digital converter (SAR ADC), the AD7091R-5, along with an efficient energy harvesting circuit based on the ADP5090 boost regulator. The ADC has a typical power consumption of 100 μW on a single 3 V supply when sampling at 22 kSPS. Typical signal-to-noise ratio (SNR) is 68 dB for a 1 kHz input signal.

The low power consumption and small form factor make this combination of devices ideally suited for portable low power applications, particularly for wearable and self-powered devices.

Figure 1. Low Power Data Acquisition System with Energy Harvesting Circuit (Simplified Schematic: All Connections and Decoupling Not Shown)

S/PDIF (Sony/Philips Digital Interface) is a high quality digital audio format that is commonly used in consumer electronics and is used to interconnect audio equipment. Many audio codecs/DSPs only support I²S as digital audio input/output, which is a problem when using these parts in circuits that need to support both S/PDIF or the AES (Audio Engineering Society) professional standard.

 

The circuit, in Figure 1, shows how to overcome this problem by connecting the ADAV801 or the ADAV803 audio codec to a SigmaDSP^® device, such as the ADAU1761.

 

The audio input in S/PDIF format is converted to I²S before processing by the ADAU1761, and the processed audio output in I²S format is converted back to S/PDIF by the ADAV801/ ADAV803. The ADAV801/ ADAV803 has a flexible digital input/output routing matrix that allows it to process audio in either I²S or S/PDIF format and output it in either format as a master or slave with the use of an onboard SRC (sample rate converter). The ADAV801/ ADAV803 support the consumer audio standard, and channel status data can be embedded in the audio stream by writing to the relevant registers in the ADAV801/ ADAV803. This is a useful feature for passing configuration information between devices. The ADAV801/ ADAV803 has a stereo DAC/ADC that can also be used to process audio as needed.

 

Figure 1. ADAV801/ADAV803 Connections for S/PDIF In/Out to ADAU1761 SigmaDSP (Simplified Schematic: Power Supply Decoupling and All Connections Not Shown)

The universal serial bus (USB) is rapidly becoming the standard interface for most PC peripherals. It is displacing RS-232 and the parallel printer port because of superior speed, flexibility, and support of device hot swap. There has been a strong desire on the part of industrial and medical equipment manufacturers to use the bus as well, but adoption has been slow because there has not been a good way to provide the isolation required for connections to machines that control dangerous voltages or low leakage defibrillation proof connections in medical applications.

The ADuM4160 is designed primarily as an isolation element for a peripheral USB device. However, there are occasions when it is useful to isolate a host device. Several issues must be addressed to use the ADuM4160 for this application. Whereas the buffers on the upstream and downstream sides of the ADuM4160 are the same and capable of driving a USB cable, the downstream buffers must be capable of adjusting speed to a full or low speed peripheral that is connected to it.

Unlike the case of building a dedicated peripheral interface where the speed is known and not changed, host applications must adapt. The ADuM4160 is intended to be hardwired to a single speed via pins; therefore, it works when the peripheral plugged into its downstream side is the correct speed, but it fails when the wrong speed peripheral is attached. The best way to address this is to combine the ADuM4160 with a hub controller.

The upstream side of a hub controller can be thought of as a standard fixed speed peripheral port that can be easily isolated with the ADuM4160, whereas the speed of the downstream ports is handled by the hub controller. The hub controller converts peripherals of different speeds to match the upstream port speed. The circuit shown in Figure 1 shows how a two-port hub chip can be used to isolate two downstream host ports in a design that can be made fully compliant with the USB specification. 

The universal serial bus (USB) is rapidly becoming the standard interface for most PC peripherals. It is displacing RS-232 and the parallel printer port because of superior speed, flexibility, and support of device hot swap. There has been a strong desire on the part of industrial and medical equipment manufacturers to use this bus as well, but adoption has been slow because there has not been a good way to provide the isolation required for connections to machines that control dangerous voltages or low leakage defibrillation proof connections in medical applications.

The application circuit shown is typical of many medical and industrial applications. 

 

The universal serial bus (USB) is rapidly becoming the standard interface for most PC peripherals. It is displacing RS-232 and the parallel printer port because of superior speed flexibility and support of device hot swap. There has been a strong desire on the part of industrial and medical equipment manufacturers to use the bus as well, but adoption has been slow because there has not been a good way to provide the isolation required for connections to machines that control dangerous voltages or low leakage defibrillation proof connections in medical applications.

The ADuM4160 is designed primarily as an isolation element for a peripheral USB device. However, there are occasions when it is useful to create an isolated cable function. Several issues must be addressed to use the ADuM4160 for this application. Whereas the buffers on the upstream and downstream sides of the ADuM4160 are the same and capable of driving a USB cable, the downstream buffers must be capable of adjusting speed to a full or low speed peripheral that is connected to it. The upstream connection must act like a peripheral, and the downstream connection must behave like a host.

Unlike the case of building a dedicated peripheral interface where the speed is known and not changed, host applications must adapt to detect whether a low or full speed device has been connected. The ADuM4160 is intended to be hardwired to a single speed via pins; therefore, it works when the peripheral plugged into its downstream side is the correct speed, but it fails when the wrong speed peripheral is attached. The best way to address this is to combine the ADuM4160 with a hub controller.

The upstream side of a hub controller can be thought of as a standard fixed speed peripheral port that can be easily isolated with the ADuM4160, whereas the downstream ports are all handled by the hub controller. However, in many cases, while it is not certifiable as fully USB compliant, a single speed cable is acceptable from a practical standpoint, especially if custom connectors are used so that it cannot be confused with a compliant device. The hub chip can be eliminated, and the design becomes very small and simple.

The ADuM4160 provides an inexpensive and easy way to implement an isolation buffer for medical and industrial peripherals. The challenge that must be met is to use this to create a bus-powered cable isolator by pairing the ADuM4160 with a small isolated dc-to-dc converter such as the ADuM5000. As with isolating any device, the services that the ADuM4160 provides are as follows: The goal of the application circuit shown in Figure 1 is to isolate a peripheral device that already implements a USB interface. It is not possible to make a fully compliant bus-powered cable because there are no 100% efficient power converters to transfer the bus voltage across the barrier. In addition, the quiescent current of the converter does not comply with the standby current requirements of the USB standard. This is all in addition to the speed detection limitations of the ADuM4160. What can be achieved is a fixed speed or switch-controlled speed cable that can supply a modest power to the downstream peripheral. However, it is a custom application that is not completely compliant with the USB standard.

 

The circuit shown in Figure 1 connects an ADAU1701 codec with an integrated SigmaDSP^® core to an SSM2306 2 W stereo Class-D amplifier and an ADP3336 low dropout regulator. The ADAU1701 has two ADCs and four DACs; therefore, it can process a stereo audio signal and output discretely processed signals to both a line-level output and an amplified output. This allows the line and amplified outputs to be processed in the SigmaDSP core with different signal processing, such as custom EQ, compressors tailored to the clip level of the specific output, or spatialization effects tuned to the specific speaker configurations. The ADP3336 generates the 3.3 V supply for the ADAU1701. The SSM2306 is a stereo 2 W Class-D amplifier with ultralow idle current and high efficiency. The amplifier does not require bulky external inductors, but it does require minimal external components and has a small system footprint. The amplifier’s voltage is not supplied from the regulator but rather directly from the 5 V system supply. This system can provide an audio signal processing path output to a low power efficient amplifier for systems such as radios, multimedia docks, or PC speakers.