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Andrew Phillips, Ben Laskowski, Shannon Abrell, Rob Swanson Project overview Project-specific success criteria Block diagram Component selection rationale Packaging design Schematic and theory of operation PCB layout Software design/development status Project completion timeline Questions / discussion eV-TEK, or Telemetry for Electric Karts, is a tool for collecting and transmitting electric go-kart parameters in a race situation. The collected data can help the driver and pit crew optimize vehicle performance and ultimately win races. An ability to report the approximate number of laps remaining on a given battery charge An ability to detect and report cell voltage anomalies An ability to sense and display kart speed An ability to track the number of laps completed An ability to log and display vehicle telemetry data Op-Amps – LM324 Operates from single 5v supply Low supply currents (700μA per amplifier) Low cost Current sense amp – INA148 Inputs need not be referenced to circuit ground Large common-mode input voltage range External ADC – MCP3204 Needed extra ADC channels This IC inexpensive and meets speed/resolution needs Battery Management Micro – PIC18F4423 13 ADC channels w/ 12-bit resolution Easily obtained Mature technology (few silicon errata items) Main Micro – PIC32MX575F256L 6 UARTs, product familiarity Wireless – XBee Pro 900MHz 6 mile range, sufficient data transfer speed Main Packaging Aluminum Aerodynamic Sits in front of driver on roll cage Detachable faceplate holds main board Driver displays Wiring connection at rear Battery Management Stand-alone package Plastic case provides electric isolation Slots for battery leads and serial line to main controller Voltage Follower Acts to increase input impedance of ADC channels Allows the use of large divider resistor values for low current drain Battery Micro Digitizes and scales battery voltages via simple code Integrates current flow over time to obtain battery charge External ADC Used to increase number of ADC channels available Interfaces to battery microcontroller over SPI Main microc0ntroller Can run up to 80MHz = 80MIPS Collects and processes data from battery packs and sensors; logs; transmits to pit area Power supply Converts 12V to 5V and 3.3V High-efficiency switchmode regulator for 12->5V conversion Linear LDO for 5->3.3V Maximum power dissipation ~2.4W Large copper pours on PCB for heatsinking Optical isolation Battery monitors float with respect to main control board 1kV of isolation provided; we require ~50V of isolation Servo motors also isolated “just in case” Side benefit: 3.3V<->5V conversion XBee module Appears as serial port to PIC32 Hardware flow control pins used to minimize risk of buffer overflow LED Drivers TLC5917 Similar to 74HC595 but includes constantcurrent output drivers Ease PCB routing – 3 wire bus instead of 13 USB-Serial converter Makes USB appear as UART for PIC32 Eases software, PCB layout Mature product, most errata fixed by manufacturer DataFlash IC 2MB EEPROM-like device for data logging Simple SPI interface; faster and more versatile than SD card Data made available for download via USB interface Voltage followers Mostly uninterrupted ground plane for noise rejection Decoupling capacitor very close to op-amps – vital for stability Current monitor Completely uninterrupted ground plane Voltage reference IC and decoupling caps very close to op-amp Digital components Separated from analog components As many extra micro pins as practical padded out Decoupling capacitors as close as practical to each power pin Power supply Linear LDO regulator Expected power dissipation ~100mW Bulk capacitor located nearby for stability Microcontroller Decoupling capacitors located physically and electrically close to chip Every pin is padded out for debugging and/or expansion Pads provided for precision oscillator module, though it should not be required Power supply Switching regulator is on top of continuous ground plane, and high dI/dt nodes are very short Linear regulator has many vias to copper plane for heatsinking Sufficient capacitance nearby for low ripple Optical Isolation Physically separate from most other critical interfaces Keepout areas near battery connectors – physical isolation is several times what is required Xbee Antenna connection is as far from other components as possible Capacitor located nearby to provide current pulses during RX->TX mode switches LED Drivers Located directly underneath 7-segment LED modules for compactness USB UART Trace length from USB connector is minimized to preserve differential nature of bus Decoupling capacitors located as close as possible EEPROM Located under PIC32 for layout convenience and to minimize length of high-speed SPI traces Decoupling capacitor nearby Battery monitors Software is essentially done Need mechanism to calibrate measurements ▪ Preliminary tests indicate this will be easy Roughly 400 lines of well-commented assembly code Main controller Began reading up on various microcontroller features (DMA, interrupt mechanism) Installed and began experimenting with C compiler Simple programs compile successfully Item Expected Completion Week Order all remaining components 8 Complete design and order main PCB 9 Complete battery monitor software 10 Assembly of battery monitor boards 10 Complete battery monitor packaging 11 Main board software complete 13 Assembly of main board 13 Complete main package enclosure 14 Final integration 15