The Pet Activity Monitor is a self-contained PCB board inside a plastic casing to make it easy to attach to your pet's collar or use the included collar. This activity monitor features a Renesas Synergy™ Platform S3-series MCU, and multiple Renesas power and analog components.
The device monitors activity and sound from your pet. It attaches to the pet's collar and can count steps taken by the pet throughout the day. It can also detect barking in dogs.
Pet activity data is logged into the MCU data flash memory making it easy for you to read this data from the monitor to see what times of the day that you pet is most active. The data collected can be downloaded to a PC via a USB port on the device. Collected data and settings can be viewed and managed through the Pet Monitor PC application.
The Pet Activity Monitor is delivered preloaded with a demonstration program. The demonstration program shows several features of the Pet Activity Monitor and source code is available as a programming example for developers.
While this design has been created specifically as a pet monitor, with some modifications to code and/or additional hardware using the non-populated PMOD connector, it could be used as a remote sensor/logger for a variety of applications.
- Accelerometer detects movement/steps
- MEMS microphone with the ISL28133 op amp for audio detection (barking)
- Utilizes low power consumption
- Low continuous active current with on/off switch
- Powered with one LIR2032 coin cell battery rechargeable by USB or +5V wall plug
- Quickly designed utilizing Synergy SSP API
- PC Application using Microsoft Visual Studio Community Edition to create a VB.NET application to interface to the device from Microsoft Windows.
- Expandable with the Serial PMOD port
Software and Tools
Evaluation board installation application (pet-monitor-setup.exe) includes the following items:
- User Manual for the ISL devices
- User Manual for the Synergy S3A3
- Pre-built PC Application
- Solution Source Project PC application
- S3A3 Embedded e2 studio Project
- Hardware Design Files
- SynergyCDC drivers for Windows OS
- User Guide for the Pet Activity Monitor Hardware
The Synergy S3A3 is powered at 3.3V and the internal oscillator is utilized to minimize component count. This is the heart of the design as it communicates over I2C to the accelerometer and uses its 14-bit ADC for both audio detection and low battery detection. The S3A3 micro is also set as a USB device for communication using the Renesas CDC driver for Windows.
The C-code for the S3A7 was written using the e2 studio IDE with the Synergy Software Package (SSP). The SSP offers an abundance of time-saving features to make designing with the S3 Synergy platform quick and easy.
The Renesas Synergy Platform (SSP) allows the RTOS, middleware, communication stacks, user interface, and detailed MCU functions to be accessed entirely through the application programming interface (API). Developers can immediately start developing end-product application code at the API level, thus eliminating the learning curve for software and MCU operation below the API. In this design, the following hardware features were utilized using simple API calls:
- Express Logic RTOS Kernel, included in the Synergy SSP
- Timers - The abundance of timers in the S3A3 MCU are used for timing certain operations
- Real-Time Clock for time keeping
- A/D converter for Audio detection and Low Battery Detection
- Data Flash of the S3A3 MCU for storing user parameters and logging activity
- USB Communication Stack for interfacing to the PC
- Use of the HOCO built-in OSC to clock the device as well as clock the USB high-speed interface without the use of an external crystal
Debugging from within e2 studio is simple and intuitive. With the addition of the low-cost Synergy J-LINK Lite hardware debugger, the code in the Pet Activity Monitor can be modified or additional functionality added.
DC/DC Switching Regulators
The ISL9120 buck-boost switcher produces the 3.3V rail that is used by the rest of the active components on the board, with a better than 90% efficiency. Even though the ISL9120 can deliver up to 800mA of power the actual power requirement for this design will draw an average of 3.4mA as it switches to different power level run modes to help keep down the power requirements. The forced bypass power saving mode can be chosen if voltage regulation is not required. The device consumes less than 3.5μA of current over the operating temperature range in forced bypass mode.
Charging / Battery Management
ISL9230 is a fully integrated high input voltage single-cell Li-ion battery charger with power path management function. This charger performs the CC/CV charge function required by Li-ion batteries. The charger can withstand an input voltage up to 26V but is disabled when the input voltage exceeds 6.6V OVP threshold. The input current limit and charge current are programmable with external resistors.
|Title||Type||Last Updated Date||Size|
|Pet Activity Monitor Users Guide
Renesas Pet Activity Monitor Reference Design Demo Kit
|19 Oct 2018||1.43 MB|
|Title||Type||Last Updated Date||Size|
Single Micropower, Chopper Stabilized, RRIO Operational Amplifier
|19 Jul 2018||2.29 MB|
|ISL9120 Data Short
Compact High Efficiency Low Power Buck-Boost Regulator
|19 Jul 2018||738 KB|
High Power Li-Ion Charger W/I-Path Management
|19 Jul 2018||1.2 MB|
WEEE Questionnaire: The WEEE Return Questionnaire is intended for the return of EEEs supplied by Renesas Electronics Europe to its customers in the European Union only.
Disclaimer: THIS MATERIAL IS PROVIDED “AS-IS” FOR EVALUATION PURPOSES ONLY. RENESAS ELECTRONICS CORPORATION AND ITS SUBSIDIARIES (collectively, “Renesas”) DISCLAIM ALL WARRANTIES, INCLUDING WITHOUT LIMITATION, FITNESS FOR A PARTICULAR PURPOSE AND MERCHANTABILITY. Renesas provides evaluation platforms and design proposals to help our customers to develop products. However, factors beyond Renesas' control, including without limitation, component variations, temperature changes and PCB layout, could significantly affect the product performance. It is the user’s responsibility to verify the actual circuit performance.