How to Design a Simple, Uninterruptible Power Supply with Supercapacitors


How can you more easily ensure a continuous, reliable power supply in power-critical applications?

How to Design a Simple, Uninterruptible Power Supply with Supercapacitors


In many applications, it is important for the supply voltage to be continuously available no matter what the circumstances. This isn’t always easy to ensure. A new concept can provide an optimal solution for an uninterruptible power supply with an extremely compact design.

There are several applications in which an uninterruptible power supply is needed. One example is the RAID systems for redundant data storage, which must be protected so that no data is lost in the event of a power failure at an inconvenient time such as during data backup activity. Systems with real-time clocks also must be supplied continuously with power. This can come from a battery or another backup solution. Other applications are telemetry applications in the automotive sector and systems for administering medications—for example, controlled insulin pumps used in the healthcare sector.

Figure 1. A typical application for an uninterruptible power supply.

Figure 1 shows a typical industrial application for an uninterruptible power supply. Here, an industrial sensor is supplied with power. The reliability of the system mainly depends on the power supply of this sensor. A linear charge regulator IC is used to charge a supercapacitor when there is available system voltage. If the system voltage drops, the energy from the energy storage system is raised to the required supply voltage level with a boost regulator. This system works well but is difficult to implement because many different energy converters are needed. Also, in many applications, it is important that no energy flows from the energy storage system back to the power supply (pictured in Figure 1). As shown in Figure 1, the supercapacitor should only power the sensor circuit and not any other electronics that may be attached to the 24 V line (shown on the left of Figure 1). The energy storage system is normally designed to supply the local load and not the complete system attached to the 24 V supply voltage. This makes Diode D in Figure 1 necessary.

Figure 2. The Continua backup concept with numerous integrated system functions.

Figure 2 shows a new concept supported by the MAX38889 from Analog Devices. It is a highly integrated backup solution called Continua™ for power rails up to 5 V. A single IC with a few passive external components is all that is required. The MAX38889 has an integrated half bridge, operated alternately in highly efficient buck and boost modes.

Figure 3. An implementation with a tiny Continua backup solution with a MAX38889 from ADI.

Figure 3 shows a complete, operable circuit. The logic and the power switches are all integrated, so just a small external chip-scale inductor and a few backup capacitors are required, apart from the supercapacitor.

The integrated high-side power switch is executed with the True Shutdown™ technology from ADI. As a result, the system voltage can be separated from the CAP voltage so that no current flows from the CAP to the system if the CAP voltage is ever higher.

While there are plenty of backup solutions for various voltage and current ranges on the market, the MAX38889 Continua is a unique backup solution with a compact design that can easily be added to the 5 V or 3.3 V supply line with minimal development and implementation effort. This solution also has a high conversion efficiency of up to 94% in charging and discharging modes to minimize the size and the cost of the energy storage.


Frederik Dostal

Frederik Dostal

Frederik Dostal是一名拥有20多年行业经验的电源管理专家。他曾就读于德国埃尔兰根大学微电子学专业并于2001年加入National Semiconductor公司,担任现场应用工程师,帮助客户在项目中实施电源管理解决方案,积累了丰富的经验。在此期间,他还在美国亚利桑那州凤凰城工作了4年,担任应用工程师,负责开关模式电源产品。他于2009年加入ADI公司,先后担任多个产品线和欧洲技术支持职位,具备广泛的设计和应用知识,目前担任电源管理专家。Frederik在ADI的德国慕尼黑分公司工作。