Highly Integrated Battery-Charging Solution with Innovative Power Path Management
Get valuable resources straight to your inbox - sent out once per month
We value your privacy
OCTOBER 7, 2019 - To achieve compact design for battery-powered devices, the battery is usually not removable and the capacity is limited by the space reserved for the battery. As a result, the operation time of the device is a major concern as devices are built with more and more power-consuming functions. To improve the portability of battery-powered devices, another auxiliary charging device with greater battery capacity is often used. These include power banks for smartphones, and charging cases for earbuds and E-cigarettes.
Power banks have been popular as an auxiliary charging device for many years because of the conflict between the increased demand for portable device performance and the limits on battery size and capacity. However, for a power bank to be considered to have good performance, compact design (for lower weight) and higher efficiency (for longer operation time) have become more necessary. There is a similar pattern with charging cases for other devices.
The traditional solution is to use a separate charging device — either a linear charger IC or switching charger IC — and a boost converter with a blocking FET to serve as power input and output, respectively (see Figure 1). However, this is not an ideal solution for meeting consumer or manufacturer demands.
Figure 1: Traditional IC Charger and Boost Converter
The MP2696A from MPS is a single-cell power management IC with flexible configuration, rich functions, and high efficiency. The MP2696A integrates as many analog circuits as possible, and operates with a simple, economical single-chip microcontroller (MCU) to provide an incredibly compact solution for mobile power products (see Figure 2).
Figure 2: High Integration with Bidirectional Operation Mode
Compared to a traditional solution, it can save one switching charger, one inductor, and one USB interface IC for the customers.
The MP2696A offers a number of features that improve efficiency and performance:
- Bidirectional operation mode to support charge and discharge using single inductor
- Integrated pass-through path with protection and independent control
- Programmable JEITA battery temperature protection thresholds
- Integrated FETs with low conduction resistance
- Integrated programmable input current limit and input voltage limit
- Automatically enters sleep mode when no load is connected
- Automatically INT output when a smartphone is connected
- Integrated enumeration interface to output maximum power for smartphone
The MP2696A communicates with the MCU through the I2C interface. It is capable of bidirectional operation in charge mode or boost discharge mode, which makes it very suitable for power bank and charging case applications. The operation mode and parameters can be flexibly set by the MCU. The operation status and any fault event are also indicated through status and fault registers.
The MP2696A is designed for a USB input, and can withstand up to 16V input voltage. As the typical input voltage of the USB port is 5V, the voltage rating of the device guarantees the robustness of the power bank even if a high surge voltage is generated at the cable plug.
The device has a programmable input current limit and input voltage limit. Up to 3A input current limit allows the MP2696A to be compliant with 15W Type-C port electrical characteristic requirements (see Figure 3). Together with the MCU, it limits the input current based on the input power supply, which ensures that it meets BC1.2 and USB Type-C specifications.
Thanks to an additional input voltage limit, the MP2696A charges the battery with an optimized charge current, reducing the charge time regardless of what type of adaptor is applied.
Figure 3: Power Flow in Charging Mode
The MP2696A can operate reversely in boost mode to provide 5V output with up to 3.6A at the SYS terminal (see Figure 4). It also has an output cable voltage drop compensation function, and an output current loop to regulate the output current when the load current exceeds the output current limit setting. When the load current increases, the MP2696A slightly increases the output voltage to ensure that the output voltage after the cable is constant, and the compensation value can be programmed.
The extreme low on resistance of integrated FETs mean the MP2696A performs with outstanding efficiency, and makes it suitable for application in highly compact designs.
Figure 4: Power Flow in Discharge Mode
Figure 5: Efficiency in Discharge Mod
Protections and Exclusive Smart Detection
The MP2696A offers robust protections in all modes. In charge mode, it has input over-voltage protection, battery over-voltage protection, a charge safety timer, and a watchdog timer. In discharge mode, it has battery under-voltage lockout and output short-circuit protection. These hardware protections guarantee safe charging in the event that the MCU software fails.
Battery temperature monitoring and protection are becoming increasingly critical in battery-powered portable devices. The Japan Electronics and Information Technology Industrial Association (JEITA) standard to optimize charging in different battery temperature conditions is becoming a mandatory feature in battery charging applications. The MP2696A not only supports this JEITA standard, but also provides programmable protection temperature points and actions within warm and cool temperature ranges (see Figure 6). The MP2696A monitors the voltage ratio between the NTC and VNTC pins for battery temperature information, since the thermistor values change with temperature. Then the MP2696A compares the measured ratio to its internal ratio difference to determine what the temperature range is, and how to adjust charge voltage and current. Therefore, the customer can change the I2C register to adjust the temperature thresholds without having to change the resistor divider on the board. Configuring the I2C register this way allows software engineers to save a great deal of effort on MCU coding.
Figure 6: Temperature Protections
When the load current falls below the programmable threshold, the MP2696A notifies the MCU that the load is removed so that the MCU can disable boost discharge and enter standby mode. The MP2696A also detects the load connections and reports to the MCU, at which point the MCU responds and wakes up the boost discharge. This eliminates the need for many external discrete components to detect the load connection.
The MP2696A also provides an analog output at the IB pin to provide real battery current information during charging or discharging, which helps the MCU estimate the battery’s capacity more accurately.