Over the past few years, wearable devices have become quite popular, in particular, smartwatches. One reason for this popularity is the possibility to monitor health and well-being in a non-invasive way. Heart Rate (HR) monitoring is one of the most important health features available in wearables. Normally, HR estimation is achieved using photoplethysmography (PPG), a common low-cost optical technique that achieves fair HR estimation in wearables. However, this technique is energy-consuming and significantly affects the device’s battery life for long-term monitoring – such as during physical exercises. In this work, we proposed a model based on linear regression and a Proportional–Integral–Derivative (PID) controller that uses an accelerometer and user’s demographics to estimate HR. The main goal of this model is to reduce power consumption since the accelerometer is a low-power sensor. We perform experiments to evaluate the performance of our method using three datasets containing more than 180 hours of data composed of a large number of different subjects. The results show that our method is competitive with a PPG-based approach and for some occasions, it is plausible to use such a model in order to save battery.