Medical Electronics


Wireless medical instrumentation benefits from new power ICs


As with many other applications, low power precision components have enabled rapid growth of portable and wireless medical instruments. However, unlike many other applications, this type of medical product typically has much higher standards for reliability, run- time and robustness. Much of this burden falls on the power system and its components. Tony Armstrong, director of product marketing power products, Linear Technology Corp. now part of Analog Devices Inc., explains


M


edical products must operate properly and switch seamlessly between a variety of power


sources such as an AC mains outlet, battery back-up and even harvested ambient energy sources. Furthermore, great lengths must be taken to protect against and tolerate faults, maximise operating time when powered from batteries and ensure that normal system operation is reliable whenever a valid power source is present. One of the current key trends fueling


growth in the portable and wireless medical instrumentation is patient care. Specifically, this the increased use of remote monitoring systems within the patient’s own home. The reason for this is trend is purely economic in nature – the costs associated with keeping a patient in a hospital are simply too prohibitive. As a result, many of these portable electronic monitoring systems must incorporate RF transmitters so that any data gathered from the patient can be sent directly back to a supervisory system within the hospital for later review and analysis by the governing physician. The manufactures and designers of


these products must ensure that they can run seamlessly from multiple power sources and have high reliability in their wireless data transmission of the data collected from the patient. This requires the designer to ensure that power management architecture is robust, flexible, compact and efficient.


Power IC solutions There are many applications in medical electronic systems that require continuous power even when the mains supply is interrupted; a key requirement is low quiescent current to extend battery life. Accordingly, power IC makers have been producing switching regulators with standby quiescent current less than 30 A since 2010. In fact, some of Linear Technology’s recent product introductions have taken this figure down to a mere 2.5 A. As a result, these products are well positioned for adoption in battery backed- up medical systems.


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in normal mode, and the switching edges are clean and predictable with no overshoot or high frequency ringing, then EMI is minimised. A small package size and high operating frequency can provide a small tight layout, which minimises EMI emissions. Furthermore, if the regulator can be used with low ESR ceramic capacitors, both input and output voltage ripple can be minimised, which are additional sources of noise in the system. As the number of power rails in many


feature-rich patient monitoring medical devices has increased, operating voltages have decreased. Nevertheless, many of these systems still require a broad range of


VOUT through a variety of battery- powered sources and their associated voltage ranges


• Ultralow quiescent current, both in operating mode and shutdown, to increase battery run time • The ability to efficiently power system rails


• Current limiting for attenuating inrush currents thus protecting the cells • Small, lightweight and low profile solution footprints


• Advanced packaging for improved thermal performance and space efficiency


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 as long as the switcher behaves predictably. If a switching regulator switches at a constant frequency


voltages from 1.xV to 8.xV for powering motors, low power sensors, memory, microcontroller cores, I/O and logic circuitry. Traditionally these voltage rails have been supplied by step-down switching regulators or low-dropout regulators. However, these types of ICs are not optimised for configurations that also incorporate a back-up battery in the system, should the main supply fail. Therefore, when a buck-boost converter is used (it can step voltages up or step them down) it will allow the battery’s full operating range to be utilised. This increases the operating margin and extends the battery run time as more of the battery’s life is usable, especially as it nears the lower end of its discharge profile. Correspondingly, DC/DC converter solutions utilised in portable medical instrumentation which may also incorporate a primary battery cell as well should have the following attributes: • A buck-boost DC/DC architecture with wide input voltage range to regulate


A new power IC that meets these


requirements is the LTC3119 from Linear Technology. It is a synchronous current mode monolithic buck-boost converter that delivers up to5A of continuous output current in buck mode from a wide variety of input sources, including single- or multiple-cell batteries, unregulated wall adapters, as well as solar panels and supercapacitors. The device’s 2.5V to 18V input voltage range extends down to 250mV once started. The output voltage is regulated with inputs above, below or equal to the output and is programmable from 0.8V to 18V. User-selectable Burst Mode operation lowers quiescent current to only 31 A, improving light load efficiency while extending battery run time. Its proprietary 4-switch PWM buck-boost topology provides low noise, jitter-free switching through all operating modes, making it ideal for RF and precision analog applications that are sensitive to power supply noise. The device also includes programmable maximum power point control (MPPC) capability, ensuring maximum power delivery from power sources with higher output impedance including photovoltaic cells. See Figure 1 for its simplified schematic. Many portable medical


systems require being powered from multiple input sources including single or multi-cell battery


configurations, wall adapters and supercapacitor stacks.


Conclusion


A large opportunity has presented itself for designing a wide range of battery-powered and/or battery backed-up medical systems. At the same time, system designers have faced difficult challenges in selecting the right power conversion solution that meets the key design objectives, including spanning the input-to- output voltage constraints, power levels and ease of design, without compromising efficiency, run time, meeting emissions specifications and solution size. Designing a solution that meets the system goals without performance compromises can be a daunting task. Fortunately, there are a growing number of buck-boost converter solutions from Linear Technology, which simplify the design, offer best-in-class features and have the ability to maximise run times in- between battery recharging cycles due to their high efficiency operation across a wide range of loads.


www.linear.com Components in Electronics October 2017 29


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