At the medium-to-low end of the power spectrum there are modest power conversion requirements such as those commonly found in “Internet of Things” (IoT) equipment, which necessitate the use of power conversion ICs that deal with modest levels of current. These are usually in the range of 100’s milliamps of current, but can be higher if there are peak power demands that are needed by an onboard power amplifier for the transmission of data or video. Accordingly, the proliferation of wireless sensors supporting the numerous IoT devices has increased the demand for small, compact and efficient power converters tailored to space and thermal constrained device form factors.
However, unlike many other applications, many industrial and medical products typically have much higher standards for reliability, form factor and robustness. As you would expect, much of the design burden falls on the power system and its associated support components. Industrial, and even medical IoT products, must operate properly and switch seamlessly between a couple of power sources such as the AC mains outlet and a battery backup. Furthermore, great lengths must be taken to protect against faults, while also maximizing operating time when it is powered from batteries to ensure that normal system operation is reliable whichever power source is present. Accordingly, the internal power conversion architecture used within these systems need to be robust, compact and require minimal heat sinking.
Power Supply Design Considerations
It is not unusual for an industrial IoT system designer to use linear regulators in a system that incorporates wireless transmission capability. The primary reason being that it minimizes EMI and noise emissions. Nevertheless, although switching regulators generate more noise than linear regulators, their efficiency is far superior. Noise and EMI levels have proven to be manageable in many sensitive applications if the switcher behaves predictably. If a switching regulator switches at a constant frequency in normal mode, and the switching edges are clean and predictable with no overshoot or high frequency ringing, then EMI is minimized. Moreover, a small package size and high operating frequency can provide a small tight layout, which minimizes EMI radiation. Furthermore, if the regulator can be used with low ESR ceramic capacitors, both input and output voltage ripple can be minimized, which are additional sources of noise in the system.
It is common for the main input power to today’s industrial and medical IoT devices to be a 24V or 12V DC source from an external AC/DC adapter and /or battery bank. This voltage it then further reduced to either 5V and/or 3.xV rails using synchronous buck converters. Nevertheless, the number of internal post-regulated power rails in these medical IoT devices has increased while operating voltages have continued to decrease. Thus, many of these systems still require 3.xV, 2.xV or 1.xV rails for powering low power sensors, memory, microcontroller cores, I/O and logic circuitry. Nevertheless, the internal power amplifier used for data transmission can require a 12V rail with up to 0.8A of current capability to transmit any recorded data to a remote centralized hub.
Traditionally, this 12V rail has been supplied by step-up switching regulators, requiring specialized switch-mode power supply design know how, and needs a large solution footprint on the printed circuit board (PCB).
A compact Boost Converter solution
Analog Devices’ μModule (micromodule) products are a solution to meet the needs of IoT systems as discussed above. These micromodules are complete System in a Package (SiP) solutions that can minimize designers’ time and solve the common problems of board space and density issues commonly found in industrial and medical systems. These μModule products are complete power management solutions with integrated DC/DC controller, power transistors, input and output capacitors, compensation components and inductor within a compact, surface mount BGA or LGA package. Designing with µModule products can significantly reduce the amount of time needed to complete the design process. Using this type of μModule family, transfers the design burden of component selection, optimization and layout from designer to the device, shortening overall design time, system troubleshooting and ultimately improving time to market.
ADI’s μModule solutions integrate key components commonly used in discrete power, signal chain and isolated designs within a compact, IC-like form factor. Supported by a rigorous testing and high reliability processes, this product portfolio simplifies the design and layout of power conversion designs.
This family of products can meet design needs for a wide range of applications including point of load regulators, battery chargers, LED drivers, power system management (PMBus digitally-managed power supplies), isolated converters, battery chargers and LED driver. As highly integrated solutions with PCB Gerber files available for every device, these power products address time and space constraints while delivering a high efficiency, reliable and with select products a low EMI solution compliant with EN55022 class B standards.
As design resources become stretched by increased system complexity and shortened design cycles the focus falls on development of the key intellectual property of the system. This often means the power supply gets put to one side until late in the development cycle. With little time and perhaps limited specialist power design resources, there is pressure to come up with a high efficiency solution with the smallest possible footprint; while potentially utilizing the underside of the PCB as well for maximum space utilization.
This is where the μModule regulator provides an ideal answer; the concept is complex on the inside, simple on the outside – the efficiency of a switching regulator and the design simplicity of a linear regulator. Careful design, PCB layout and component selection are very important in the design of a switching. When time is short or power supply design experience is limited, this ready-made regulator saves time and reduces risk to the program.
A recent example of ADI μModules, is the LTM4661 synchronous step-up uModule regulator in a 6.25mm x 6.25mm x 2.42mm BGA package. Included in the package are the switching controller, power FETs, inductor and all support components. Operating over an input range of 1.8V to 5.5V, it can regulate and output voltage of 2.5V to 15V, set with a single external resistor. Only bulk input and output capacitor are needed.
3.3V to 5V Input, Delivering 12V at up to 800mA with an External Clock
This regulator is efficient and can deliver efficiencies of greater than 87% when stepping up from a 3.3V input to a 12V output. See Figure 2 efficiency curve below.
Efficiency vs. Output Current for the LTM4661 from a 3.3V Input to Outputs Ranging from 5V to 15V
Also, Figure 3 shows the measured thermal picture of the regulator running form a 3.3V input to 12V at 800mA DC current with 200LFM airflow and no heat sink.
Thermal Image of LTM4661; 3.3V Input to 12V Output at 0.8A, 200LFM Air Flow and No Heat Sink
The deployment of IoT equipment has exploded in recent years and includes a wide variety of products for the military and industrial application spaces. A new wave of products, including sensor-filled medical and scientific instrumentation have been key market drivers in recent years and are only now starting to see signs of significant growth. At the same time, the space and thermal design constraints of these systems has necessitated a new class of power converters that can deliver the necessary performance metrics of small, compact and thermally efficient footprints to power the internal circuits, such as the power amplifier. Fortunately, devices such as this recently released step-up regulator elevates the power supply designers task.
Finally, using these regulators make sense in these types of environments since they can significantly reduce the debug time and allow for greater board area usage. This reduces infrastructure costs, as well as the total cost of ownership over the life of the product.