In clinical medical, heart rate (HR) is an important vital sign for doctors to access the general health of a person. Depending on the various physiological condition, like arrhythmia, anxiety and so forth, the HR changes accordingly. What’s more, normal HR varies from person to person. Knowing yours can be an important heart-healthy gauge. In addition to clinical medical, monitoring HR when exercising can help us to maximize the effect of exercising and prevent from getting injured. Benefits from the advantages mentioned above, the demands for HR monitors have increased in the recent years. In the application of real-time HR monitoring, Electrocardiogram (EKG) is traditional ways to monitor heart rate. EKG encounters high cost and inconvenience. Recent trend for HR monitoring is Photoplethysmography (PPG), which is low-cost, user-friendly and can be integrated into wearable devices. However, PPG will be interfered by motion artifacts (MA). Past works for HR monitoring from motion-corrupted PPG is not workable in real applications. As a result, we require additional information to analyze the signal components corresponding to MA. Tri-axis accelerometer is helpful to analyze the components of MA and suppress them from the corrupted PPG signal. In this work, we propose a motion-tolerant HR monitoring system with PPG signal and tri-axis accelerometer. The system has two key parts, motion artifact cancellation and spectral peak tracking. We propose a low-complexity motion artifact cancellation based on adaptive noise cancellation (ANC) to suppress the MA components effectively and a robust spectral peak tracking based on Kalma filter to track the peak corresponding to HR on the spectrum. This work has good accuracy of HR monitoring and show the potential to apply on wearable device in real application.