Project

# Title Team Members TA Documents Sponsor
14 Outdoor Smart Dog Feeder
Kevin Shi
Lucas Duduit
T'Andra Newby
 Nithin Balaji Shanthini Praveena Purushothaman design_document3.pdf
final_paper1.pdf
other2.pdf
photo1.jpeg
photo2.jpeg
photo3.jpeg
presentation1.pdf
proposal2.pdf
# Outdoor Smart Dog Feeder
## Introduction
An automatic dog feeder relieves a dog parent of the habitual task of refilling their pets' bowls. Due to work and travel, it can sometimes prove to be difficult to keep track of and complete this task on a regular schedule. A simple solution of a self feeder is not a viable action because most dogs cannot be self governed when it comes to how much they eat. Overeating results in gorging sickness, canine obesity, and sometimes death. An automatic smart dog feeder ensures that the dog only gets the amount of nutrition they need throughout the day.
## Design Concept
For a 445 project, it is important to note that the market for indoor automatic dog feeders is saturated with hundreds of brands and models; However, the choices for smart dog feeder for larger outdoor/indoor-outdoor dogs are limited. The project proposed is to fabricate a heavier and robust feeder that will dispense food into a sheltered reciprocal based on users input for parameters such as quantity and frequency. The mechanism of dispensing begins at the reservoir (1) this is above an auger chamber aided by gravity this auger will be driven by a motor into a reciprocal (2). The reciprocal also contains a scale to allow the unit to know how long to run the auger motor based on the user's settings. Once the food is dispensed into the reciprocal the lid is able to open when the RFID tag is in proximity.
## Specifications of design
- Scheduled feeding times and amount. (3)
- Active weighing to monitor pet's eating habits; While also not allowing continued dispensing resulting in overfill.
- RFID proximity access to only permit the pet to eat from reciprocal.
- Solar powered with internal battery bank
- User notifying system for low feed reservoir or low/loss of power (3)
- Tracking feeding paterns to alert owner of illness or loss of appetite (3)

## THE STM32 Cortex M0+ MICROCONTROLLER I/O:
## INPUTS
- 2.4 GHz transceiver (4)
- Digital scale signal (9)
- Voltmeter for charge state of battery (8)
- RFID digital signal (7)
## OUTPUTS
- 2.4 GHz transceiver (4)
- auger motor (5)
- reciprocal lid motor (6)

## Footnotes
- (1) Sheetmetal container formed into a box/silo that holds 50-60 lbs of dog food
- (2) The reciprocal is sheltered and protected by a hinged and motor driven lid.
- (3) An app for android or a raspberry pi application for user to unit communication
- (4) MKW41Z for Bluetooth low energy app communication
- (5) Servo motor dynamic loads
- (6) Stepper motor for holding torque
- (7) Grove - 125KHz RFID Reader
- (8) two resistors
- (9) Ardest A/D Converter Weighing Sensor HX711 Balance Module for Load Cell MCU AVR Arduino

ATTITUDE DETERMINATION AND CONTROL MODULE FOR UIUC NANOSATELLITES

Shamith Achanta, Rick Eason, Srikar Nalamalapu

Featured Project

Team Members:

- Rick Eason (reason2)

- Srikar Nalamalapu (svn3)

- Shamith Achanta (shamith2)

# Problem

The Aerospace Engineering department's Laboratory for Advanced Space Systems at Illinois (LASSI) develops nanosatellites for the University of Illinois. Their next-generation satellite architecture is currently in development, however the core bus does not contain an Attitude Determination and Control (ADCS) system.

In order for an ADCS system to be useful to LASSI, the system must be compliant with their modular spacecraft bus architecture.

# Solution

Design, build, and test an IlliniSat-0 spec compliant ADCS module. This requires being able to:

- Sense and process the Earth's weak magnetic field as it passes through the module.

- Sense and process the spacecraft body's <30 dps rotation rate.

- Execute control algorithms to command magnetorquer coil current drivers.

- Drive current through magnetorquer coils.

As well as being compliant to LASSI specification for:

- Mechanical design.

- Electrical power interfaces.

- Serial data interfaces.

- Material properties.

- Serial communications protocol.

# Solution Components

## Sensing

Using the Rohm BM1422AGMV 3-axis magnetometer we can accurately sense 0.042 microTesla per LSB, which gives very good overhead for sensing Earth's field. Furthermore, this sensor is designed for use in wearable electronics as a compass, so it also contains programable low-pass filters. This will reduce MCU processing load.

Using the Bosch BMI270 3-axis gyroscope we can accurately sense rotation rate at between ~16 and ~260 LSB per dps, which gives very good overhead to sense low-rate rotation of the spacecraft body. This sensor also contains a programable low-pass filter, which will help reduce MCU processing load.

Both sensors will communicate over I2C to the MCU.

## Serial Communications

The LASSI spec for this module requires the inclusion of the following serial communications processes:

- CAN-FD

- RS422

- Differential I2C

The CAN-FD interface is provided from the STM-32 MCU through a SN65HVD234-Q1 transceiver. It supports all CAN speeds and is used on all other devices on the CAN bus, providing increased reliability.

The RS422 interface is provided through GPIO from the STM-32 MCU and uses the TI THVD1451 transceiver. RS422 is a twisted-pair differential serial interface that provides high noise rejection and high data rates.

The Differential I2C is provided by a specialized transceiver from NXP, which allows I2C to be used reliably in high-noise and board-to-board situations. The device is the PCA9615.

I2C between the sensors and the MCU is provided by the GPIO on the MCU and does not require a transceiver.

## MCU

The MCU will be an STM32L552, exact variant and package is TBD due to parts availability. This MCU provides significant processing power, good GPIO, and excellent build and development tools. Firmware will be written in either C or Rust, depending on some initial testing.

We have access to debugging and flashing tools that are compatible with this MCU.

## Magnetics Coils and Constant Current Drivers

We are going to wind our own copper wire around coil mandrels to produce magnetorquers that are useful geometries for the device. A 3d printed mandrel will be designed and produced for each of the three coils. We do not believe this to be a significant risk of project failure because the geometries involved are extremely simple and the coil does not need to be extremely precise. Mounting of the coils to the board will be handled by 3d printed clips that we will design. The coils will be soldered into the board through plated through-holes.

Driving the inductors will be the MAX8560 500mA buck converter. This converter allows the MCU to toggle the activity of the individual coils separately through GPIO pins, as well as good soft-start characteristics for the large current draw of the coils.

## Board Design

This project requires significant work in the board layout phase. A 4-layer PCB is anticipated and due to LASSI compliance requirements the board outline, mounting hole placement, part keep-out zones, and a large stack-through connector (Samtec ERM/F-8) are already defined.

Unless constrained by part availability or required for other reasons, all parts will be SMD and will be selected for minimum footprint area.

# Criterion For Success

Success for our project will be broken into several parts:

- Electronics

- Firmware

- Compatibility

Compatibility success is the easiest to test. The device must be compatible with LASSI specifications for IlliniSat-0 modules. This is verifiable through mechanical measurement, board design review, and integration with other test articles.

Firmware success will be determined by meeting the following criteria:

- The capability to initialize, configure, and read accurate data from the IMU sensors. This is a test of I2C interfacing and will be tested using external test equipment in the LASSI lab. (We have approval to use and access to this equipment)

- The capability to control the output states of the magnetorquer coils. This is a test of GPIO interfacing in firmware.

- The capability to move through different control modes, including: IDLE, FAULT, DETUMBLE, SLEW, and TEST. This will be validated through debugger interfacing, as there is no visual indication system on this device to reduce power waste.

- The capability to self-test and to identify faults. This will be validated through debugger interfacing, as there is no visual indication system on this device to reduce power waste.

- The capability to communicate to other modules on the bus over CAN or RS422 using LASSI-compatible serial protocols. This will be validated through the use of external test equipment designed for IlliniSat-0 module testing.

**Note:** the development of the actual detumble and pointing algorithms that will be used in orbital flight fall outside the reasonable scope of electrical engineering as a field. We are explicitly designing this system such that an aerospace engineering team can develop control algorithms and drop them into our firmware stack for use.

Electronics success will be determined through the successful operation of the other criteria, if the board layout is faulty or a part was poorly selected, the system will not work as intended and will fail other tests. Electronics success will also be validated by measuring the current consumption of the device when operating. The device is required not to exceed 2 amps of total current draw from its dedicated power rail at 3.3 volts. This can be verified by observing the benchtop power supply used to run the device in the lab.