2023 System Architecture
Summary
This page describes the top-level view of the 2023 competition airframe, and contains references to sub-pages with implementation specific details. This page will be finalized as of Nov 6, 2022. Any changes after that point must follow the formal RFC proces. Ping Anni for more details.
Please make ur RFC using the following link: 2022-2023: Request For Change Home Page
Acronyms & Links
[The Drone] - The drone as a whole, including electronic components and integrated software systems.
[(the) Airframe] - Fuselage, wings, control surfaces, & mechanical components used to connect them
[ZPSW] - ZeroPilot Software ZeroPilot 3.0 Architecture
[ZPHW] - ZeroPilot Hardware
[IMU] - Inertial Measurement Unit
[GPS] - Global Positioning System (device to capture GPS data)
[ESC] - Electronic Speed Controller, Motor Controller
[GS] - Groundstation
[Tracking Antenna][Antenna Tower][Tracking Tower] - all tracking antenna systems.
[T_Telem] - telemetry tracking tower
[T_VRX] - video receive tracking tower
[GSPC] - groundstation PC
[GS_SW] - groundstation software
[GUI] - groundstation gui (software gui for user).
[OSD] - on screen display (attitude information overlayed over video feed
[MUX] - Video Mux
[rfd900x] - RFDesign RFD900x Modem (singular)https://uwarg-docs.atlassian.net/l/cp/LPn8hwCv
[Competition Design Outline] [CDO]Competition Design Outline
[Competition Requirements] [CR]Competition Requirements
[VN-300] [VectorNav VN-300] 2023-03-26 - VN-300 Rugged Harness
Architecture
The architecture of a drone can be found in the [Competition Design Outline]. <# iterations> iterations of the drone will be created, at <#milestones>. <# final copies> of the drone will be created in “competition spec”. Our system will meet the requirements in [Competition Requirements].
Our general architecture has the following hardware elements:
Airside Components:
All components marked “Optional” will not be present for the May 2023 Competition
Airframe (Wings, Fueselage, tail)
Power:
2 6s batteries, potenmtially more auxilliary power sources.
1 pdb
Propulsion:
4 lift motors + ESC’s + Props
1 push motor + ESC’s
T-Motor AT4130 230Kv AT4130 Long Shaft_AT Series_Motors_Fixed Wing_T-MOTOR Store-Official Store for T-motor drone motor,ESC,Propeller (tmotor.com)
APD 120FX[3] 120F3[X] — Advanced Power Drives
APC 17*10 Propeller.
8 Servos
Compute
Mandatory:
Optional:
Jetson TX2 + Carrier Board
NVIDIA Jetson TX2i: https://www.arrow.com/en/products/900-83489-0000-000/nvidia
Connect Tech Quasar carrier board: https://connecttech.com/product/quasar-carrier-nvidia-jetson-tx2/
Custom STM Flight Board (Nucleo OR ZP3)
ZP3 Custom Hardware Specifications:
ZP3 MCU: STM32L562ZET6Q
Add ZP3 Interface: https://warg.365.altium.com/designs/14CBC2A9-7887-4911-B7F1-874B17856231
Add ZP3 Primary: https://warg.365.altium.com/designs/8E6687CB-1A15-4D5A-BEAD-9E45C5E56743
Add ZP3 Hardware Link: ZeroPilot 3.0 Hardware (ZP3HW)
Nucleo STM32L552
Peripherals
Mandatory
2 FPV cameras + video mux
2 Caddx Baby Ratel 2 https://www.getfpv.com/caddx-baby-ratel-2-1200tvl-1-8mm-fpv-camera.html
1 Video Mux
1 OSD board
1 1.3 GHz VTX
Mateksys VTX-1G3SE http://www.mateksys.com/?portfolio=vtx-1g3se
or
Pairs with singularity 1280 LHCP side exit
1 RFD900x
stock antennas
Set of LED’s
green LED’s for PAX aboard light
LED’s for aircraft nav-lights
1 HereFlow Optical Flow Sensor
1 Lidar module
TFMini-S I2C Micro Lidar Module https://ca.robotshop.com/products/benewake-tfmini-s-micro-lidar-module-i2c-12m
1 VN-300 Inertial Sensor
1 NEO-M8 GPS Sensor w/safety switch (pixhawk terminated)
1 Airspeed Sensor
Optional
1 CV Camera
(potential) 1 Dragonlink 433 OR LTE connection
1 SD Card for logging on ZP3.
incl SPI → SD board
1 SD Card for Jetson
1 Mateksys Optical Flow sensor
Mateksys 3901 L0X http://www.mateksys.com/?portfolio=3901-l0x
Arm/Disarm board.
Groundside Components:
Telemetry & Control
1x Telemetry radio
RFD900X RFD900x Modem - RFDesign
stock antennas
1x Control Relay
TBS Tracer System TBS Tracer - true connectivity (team-blacksheep.com)
Ground Station Computer (WARG Laptop)
2x Controllers
TX16S Mk II (ELRS) TX16S Mark II Radio Controller (Mode 2) – RadioMaster RC
“blue” controller to house Tracer TX as master.
“pink” controller to connect to blue as slave.
TRRS cable
1x Tripod
Video
1x 1.3 GHz Long Range Video Receiver
ReadyMadeRC 1.3GHz VRX RMRC 900MHz 1.3Ghz High Performance Receiver w/ Custom Tuner - RMRC (readymaderc.com)
pairs with a TrueRC singularity 1280 antenna
RCA output to 5.8 Video Relay
1x 5.8 GHz Video Relay
Rush Tank Race II TANK RACE II VTX – RUSHFPV or any other 5.8GHz capable video transmitter
pairs with a rush cherry RHCP antenna, with U.FL Termination
Takes RCA input from the 1.3 GHz System
1x 5.8 GHz VRX
any 5.8GHz VRX. In our case, we have:
2x 5.8 monitors
1x RC832
Chosen receiver will be given a rush cherry RHCP antenna, terminated in SMA.
RCA → USB Adapter
any RCA → USB adapter https://www.amazon.ca/JMGO-Digital-Converter-Capture-Support/dp/B0B5THBF6G
1x Goggles (WARG Sponsored)
EMAX Transporter 2 Transporter 2 Analog FPV Goggles w/ DVR and Removable Screen | Emax USA (emax-usa.com)
takes rush cherry stem SMA antenna
5.8 GHz Video Monitor
any 5.8 ghz video monitor.
1x Tripod
Optional Tracking Antennas
Tracking Antenna Telem
900 MHz Yagi or patch antenna
RMRC patch antennas https://www.truerc.ca/shop/900mhz-3/receiver-long-range-900mhz-3/x-air-900
Nucleo F401
Omnidirectional antenna
same as transmitter on drone?
BMX160 IMU
NEO M.8 GPS
Tracking Antenna VRX
1.3 GHz Patch Antenna
Nucleo F401
BMX 160 IMU
NEO M.8 GPS
(potentially) 5.8GHz VTX
Airside Architecture
Now that we know what components are going on our drone, let’s talk about how they’re going to be laid out on the drone itself. This page will be finalized on Nov 6, 2022. After that date, any changes must go through a formal RFC process involving all subteam leads.
Airframe Design
Propulsion
lift, push, offsets, spacing?
Wings
wongs.
Servo locations? numbers? gg
Tail Section
Rudder/elevator
Fuselage
Fuselage is main passenger compartment?
Avionics Compartment
The avionics compartment will house all the airside compute. The compartment should be weather resistant, but be mounted on the drone in a way such that all electronics are easily accessible and serviceable with minimal effort (ideally no screws removed to plug/unplug connectors from any of the onboard computers.
The avionics compartment should allow for airflow and cooling over critical components. The Pixhawk should be mounted center with the COG, and peripherals should be mounted as explained below.
Sensors may be placed in the avionics compartment, but they should be mounted where they make sense. See below
Landing Gear
Design, limitations, etc.
Lighting
Airside Hardware Layout
System Level Electrical Placement & Routing Guidelines/Information:
The frame should not be electrically connected (aka should be at floating potential)
Complies with: UL1740
This can be checked with a DMM (when the system is not powered)
This means that if a PCB we are using has electrically connected mounting holes we need to take proper steps to achieve isolation
Sometimes PCB mounting holes are electrically connected to a GND plane for thermal reasons so we should also approach thermals with caution on sensitive electronics
Conformal Coating can be used within reason
The pro of conformal coating is waterproofing and makes it harder to accidentally should with a screw driver
The con of conformal coating is it prevents heat from leaving a PCBA
So anything that is conformal coated should receive a thin layer at most
Another con is that it can be annoying to remove in the case of reworking a PCBA
For example it would be fine to conformal coat a flight controller that runs cool
However, for example an RF transmitter we would want to approach with more caution
We could place a large heatsink on the primary chip(s) using thermal paste
Then we could consider conformal coating the other portions of the board
Cables, especially longer cables, should be within sheaths when reasonable
This offers protection against abrasion during natural flight vibrations
Exception to this rule is shorter cables that are placed further from anything that could be abrasive, specifically cables purely within the avionic compartment of our aircraft
Avoid loops in cable runs if possible
Varying conductor types should be separated when reasonable
Generally we consider four different types of cables: Digital, Analog, Power, & Coax/Rf
Digital: Characterized by signals with fast edges
Definition of a fast edge in this context and some examples to be added by an EE
Generally transcieving in 0 and 1 states asynchronously or synchronously
I.E. a GPS module’s cable connection to our flight controller is digital
An IMU is an example of a particular digital device that is sensitive to external noise.
Analog: Characterized by signals with slow edges
Definition of a slow edge in this context and some examples to be added by an EE
Generally transcieving data in varying voltage states
Though some protocols we consider analog will also transmit some digital data as well
I.E. a hobby fpv analog video camera has an analog data output
An analog video feed out of an analog camera is an example of a particular digital device that is sensitive to external noise.
Power: Characterized by constant voltage varying current designed for power transmission
Generally the voltage is constant though higher frequency noise may be present
These conductors can have significant current pulses
I.E. a connection from a battery to an ESC
Coax/Rf: Characterized by oscillating signals across the spectrum (~20kHz to ~300Ghz) intended for wireless transmissions and notably contained within a coaxial cable
A coaxial cable, specifically for our applications utilizing an SMA or RP-SMA connector, is generally used to guide sensitive RF signals between transceivers & antennas.
It is also worth noting antenna placement is critical, this is noted below in more detail
SMA & RP-SMA connector info should be found in the corresponding connectors arch doc section.
Because coaxial cables offer strong noise immunity the routing constraints of these cables are looser than others
Coax cables are very good at eliminating outside noise
For further information see: Coaxial cable
Each of these type of conductors should be physically grouped together, however, each type should be separated
I.E. All power stuff near each other, all digital near each other, but power separated from digital
This grouping and separation is physical distance, though of course there are other factors
Within PCBAs these groups may be mixed, this is fine, we will assume the PCB designer has taken the proper care to avoid issues as necessary
RF Transceiver Care
An RF transmitter should not be turned on (given input power) without a proper antenna connected as this can permanently damage the transmitter
Possible violations of this policy should be reported in Discord and transmitters should be labelled as damage (notably degraded performance) may not be immediately evident. We don’t want to blame each other, stuff happens, we just want to note it for the future! If you do not feel comfortable stating this publicly feel free to DM a lead you’re comfortable speaking to who can relay the message without naming names.
Transmitters generally get warm
They require a lot of power and therefore require some cooling
They are sometimes designed to be mounted outside an airframe for ambient cooling of wind passing the frame. As we may not be doing this we need to approach this with caution.
Notes regarding conformal coating are above.
The lower the frequency the longer the distance we can get for the same output power generally
The higher the frequency means more bandwidth generally
Antenna mounting
GPS sensors in particular are to our 900 MHz and 1.3 GHz transceivers and should be mounted away from antennas operating at these frequency ranges
GPS frequencies are fixed frequencies are1100MHz and 1500MHz
Our transceivers will hop around frequencies around their range looking for available channels so they are capable of hopping close to GPS frequencies and causing issues
For context it’s worth noting a 900MHz and 1.3GHz transceiver are capable of stepping on each others frequencies as well
For further reference see Guide: 1.2GHz -1.3GHz FPV Video System - Oscar Liang & GNSS Frequencies and Signals
Radio waves do not like to change medium
Specifically they do not like to pass through materials of varying dielectric constant
Passing waves through some varying materials may be fine, but be careful!
At the frequencies WARG operates at (6 GHz and below) foam will not have a considerable impact on signal integrity
Rain will have a measurable impact on signal integrity
This means mounting antennas outside of cases/airframes and providing LOS when reasonable
Antenna polarity should be deliberate
Antennas that use diversity should be mounted not in the same plane
There are different types of diversity
The VN-300 employs “Spatial Diversity”
The RFD9000 employs “Polarization Diversity”
Antenna diversity is not the same as true diversity
Antenna polarity matching follows the below graphic
(Antenna Mounting Continued)
Ground antenna should be mounted with as much distance away from the ground as possible
This is to reduce ground reflection and has a considerable effect on reliability of an RF link
Antenna spacing should be minded
Any device with diversity (multiple antenna inputs) should have it’s antennas mounted with some spacing between them. Always follow manufacturer guidance here.
IE our VN-300 has specific manufacturer recommendations regarding recommended spacings and clearances
Different devices should have their antennas spaced out
See notes about frequencies and channels above.
Some notes about lightning
This entire section can be ignored for WARG purposes on nice days and the odds of a lightning strike are relatively low so don’t worry too much about these guidelines
As long as the current from a lightning strike is allowed to pass through your structure relatively unimpeded it will not harm the system
Notably isolating important electronics from the structure is important for this, see above.
To ensure this is possible having a somewhat conductive frame helps
This is not possible for composite frames and thus more complex techniques can be employed
Lightning likes to, if possible, enter and exit through sharp points
Ensuring that the sharpest points on a region of the system are all not electrical elements (notably antennas) will ensure lightning passes where we want it to!
A side safety note is that people are also relatively sharp points sticking out of the ground, however, unlike structures, you aren’t replaceable.
Be sure in lightning prone weather that people are not the path of lowest impedance for a lightning strike! This can be done easily by ensuring taller, pointier, grounded structures are nearby humans.
For ground equipment (towers and stations) grounding rods can be used
Notably this may not be possible for ecological reasons as well as if our ground station is on pavement
Grounding rods should connect into the earth (with a pointed end) electrically to the sharpest point at the peak of the structure
Ideally, as mentioned above, the entire structure is conductive which makes this easier to achieve.
Layout Introduction
The plane will be comprised of 5 main sections: the fuselage, cabin, avionics compartment, wings, and tail. The avionics + passenger compartment will be part of the main fuselage, while the wings & tail will house more electronics. All mandatory airside compute & airside peripherals must be mounted.
Compute
The Holybro PX_ system should be placed as close to the center of rotation of the drone as possible, offset in ONE axis only to allow for the installation of the VectorNav VN-300 module. There is an arrow on the top of the Pixhawk, which should point toward direction of forward flight. Keep in mind that wires need to be accessible from the “back” of the pixhawk (I/O & FMU Output banks), as well as from the side for USB debugging as well as retrieval of the SD Card.
There is no strict need to electrically isolate the system (the baseboard & cube are already protected), but it could be helpful to mount the system on vibration damped material (yellow sticky tack is good for this purpose).
Batteries & Power Distribution
Batteries and Power Distribution shall be mounted in front of the passenger compartment, under the same access lid as the pixhawk & various other PDB/Sensors. Batteries will be multiple 6S batteries harnessed together to provide a total output of 12S.
The battery box should be easily accessible from the top so that battery swaps may be easily accomplished during task #2, and should be weatherproof and house the PDB, Batteries, and necessary power connectors in a manner that makes upkeep & plugging/unplugging/probing connectors easily.
Transmitters
Both transmitters (RFD900x, 1.3ghz VTX), should be placed in areas with adequate cooling/airflow. Airflow can be introduced passively (i.e., drone is moving through the air), or actively (i.e. a fan). These devices are not weatherproof, and care should be taken to place their antennas away from any other RF sensitive devices. Devices such as cameras, unshielded signal wires, IMU’s, and GPS devices may experience large amounts of RF noise if placed too close to the antennas.
The RFD900x will use the stock dipole antennas (the long ones), which means that RF Noise generated by the RFD900 may be fairly close to the source. It is recommended to use coaxial cable extensions to mount the antennas at least 20cm away from each other. Recommendations to put one antenna along the edge of a wing, and to place the other antenna vertically along a vertical stabilizer or landing gear. Maintain one antenna perpendicular to horizon and one antenna parallel to horizon.
The VTX will use a coaxial cable extension to a side-exit singularity 1280 antenna mounted on the horizontal stabilizer. The antenna may be mounted inside or on top of the horizontal stabilizer. Maintain antenna deadzone perpendicular to horizon.
Cameras & Related Peripherals
There will be three pilot cameras. All cameras should offer +/- 10 degrees of adjustment minimum, up to +/-30 degrees is desirable from their intended direction. The mounting locations are as follows:
forward facing at front of drone, level with horizon.
downward facing, perpendicular to horizon.
Downward facing, at a horizon angle of -30 to -45 degrees mounted high at the rear of the drone.
The forward facing camera will be the primary in-flight camera used during transition & fixed wing flight, while the downwards facing cameras may be used during takeoffs/landings as well as searching for landing pads.
There are currently no plans to motorize or otherwise be able to move the cameras in flight. This means they must maintain a pre-set fixed position in flight.
All three cameras will be wired into the Video Mux Switch, which will then pass a single analog video feed to the OSD, before being passed to the VTX. See Airside Electrical Layout for more details on wiring and interconnects. The OSD and Video Mux should be placed inside the avionics compartment, and although they do not require cases, it may be prudent to electrically isolate them from other conductive materials such as: carbon fiber, exposed wires, etc.
GPS Sensors
The VN-300 receiver (red box) should be placed as close to the center of rotation of the plane as possible, with the axis aligned (x is forward, refer to ZPSW Documentation for more detail). This can be done above or below the passenger compartment, but should be in a weatherproofed section of the plane with low external RF interference.
Both VN-300 receptors & their grounding planes should be placed 1M apart, facing directly upwards, above other elements. These will be mounted inside the wings.
One NEO M9N GPS Module needs to be placed in an easily accessible location on the drone. The kit comes with a mounting stand which means that it could be placed on top of the drone, away from RF noise, but there is no strict requirement for this. The safety switch on the GPS module must be easily accessible. See Airside Electrical Layout for wiring limitations.
Peripheral Sensors
Airspeed sensors should be placed in clean air, facing forwards.
Optical flow sensors & rangefinders or lidars should be mounted at the bottom of the drone, in a sensor cluster without obstructions (clear or otherwise) in the fov of the devices.
It is mandatory to have at least 1 hereflow and 1 tfminis lidar module, the rest of the sensors are optional.
Airside Electrical Layout
Please see https://uwarg-docs.atlassian.net/wiki/spaces/ARCHS22/pages/2200076334 . EE Team member to update with more specifics @Daniel Puratich
General Wiring Guidelines
Servos connect to I/O Output and follow AETR, L->R
1/2/3/4 Aileron (LO/LI/RI/RO)
5/6 Elevator (LE / RE)
7/8 Rudder (LR / RR)
Motors connect to FMU 1-5
Mot X : FMU X
FMU 6/7 for Aux Lighting
FMU 8 for Video Mux
Telem 1 → OSD
Telem 2 → RFD900x
will need external Power
CAN1 → Hereflow
GPS1 → M9N
VN300 → GPS2
Power Architecture
The drone will run a 12S power system. The specific sources and rails are listed below:
VBAT (4x Turnigy 6S LiPo batteries, 2 pairs in series, each pair connected in parallel.):
APD PDB500[X] (500A continuous limit):
12S rail (Total current draw: 300A MAX):
V505 KV260 Lift Motors x 4 (60A MAX each)
AT4130 230Kv Push Motor x 1 (60A MAX)
12V rail (3A limit. Total current draw: 2.3A MAX):
RGB LED strip (~1.7A MAX)
DC Cooling Fan (0.59A MAX)
5V rail (3A limit. Total current draw: 1.4A MAX):
Pixhawk 6
HS-311 Servo Motors x 8 (1.3A MAX)
Cytron H-Bridge Driver (0.1A MAX)
Pixhawk 6 (5V step-down from 12S BEC):
VN-300 x 1 (0.323A MAX)
Turnigy 3S Battery
A detailed description of how each device is being powered and which connector type is outlined in the following document: https://uwarg-docs.atlassian.net/wiki/spaces/EL/pages/2208727041.
Wiring
All of the wires for the sensors will be pre-run through the frame in dedicated channels, with connectors left exposed near the sensor compartments and the avionics compartment. This means that any time a sensor needs to be replaced, we do not need to re-wire the entire sensor. this also means that when we need to re-wire the flight computers, we can use the cables that are already connected to the interface connectors an simply plug in a few large connector banks to our dev interfaces. Running more cables through the channels should be supported, but all necessary cables should hopefully be routed during assembly (or when it is easiest).
All sensors shall be connected to the respective device owners listed in the hardware components section. There will also need to be a single UART connection between ZP ↔︎ Jetson, as well as multiple (at least 5) communication wires available between the PX5 and ZPHW.
Connector Standardization
Gender Decoding
Gender conventions regarding what goes where are defined below.
Gender is defined by the metal conductors in all cases. Plastic housing should be ignored when deciphering gender. The manufacturer’s dictated gender decision takes preference over this, however, it will be clearly iterated here if that is the case.
XT series connectors are convenient, common in the hobby world, fairly reliable, and relatively cheap and will therefore be employed for all WARG DC power connections whenever possible.
COTS PCBAs after require solder pad connections which we will accommodate, but breakout to our prioritized connectors whenever possible.
XT60 connectors will be prioritized for any sub 150 A pulsed DC connection
For ESCs and anything smaller this should be prioritized
XT60-F is on batteries and so the XT60-F should be used on any voltage source and XT60-M should be used on any load. This gender convention is also used in the COTS world and keeps things simple.
Manufacturer PN Gender: “-F” is female & “-M” is male
Custom hardware will use XT60PW series connectors and follow the above gender convention.
XT30s will be avoided when possible for simplicity
While XT30s are smaller and meet our current requirements for lots of low voltage loads in order to minimize the amount of connectors we need to stock and use XT30s will not be prioritized when an XT60 can be used.
COTS loads and sources with XT30s will be adapted to XT60 through harnessing
XT90 connectors will be used for any greater than 150 A pulsed DC connections
COTS higher current 6S and above batteries often ship with these XT90s and so we will accommodate such a design decision as they are rated for the higher current.
Anti-spark XT90s should be used whenever possible to limit sparks from in-rush condition though this may not always be possible.
XT90 battery input splitting into ESC and converter connections should be done on a properly specified PCB with XT connections done in harnessing.
AC Mains is not used on any WARG aircraft and therefore a connector will not be specified
No voltage sources exceeding 55 V during nominal continuous operation are to be present on aircraft due to a lack of necessity and safety concerns
ESC BLDC Motor Controller Phase connectors will be specified in the future and require more decisions in the future.
3.5mm banana connections is a solid option from the hobby world, but they can be a pain. Other size banana connections may be used as well on smaller aircraft as we come up with more specific decisions.
Gender Convention: Female on ESCs, Male on motors
Anderson Power pole series connectors are promising and have significant use in FRC, but will require validation before we fully adopt them in place of the ol' banana connectors
Gender is not present on these but ideally three different colors are used.
PWM Signal Connections
Should be done with with standard twisted PWM cables. Ideally locking stuff so it doesn’t pull out easily.
Simplest solution is often the best so sticking with these seems ideal.
Gender convention: Male pins on the signal generator and female sockets on the signal receivers.
We will use mechanical locking on the headers, copying how it is done in Vex to lock the PWM connectors into the board they connect to.
Where this is not viable we will defer to hot glue
Other low voltage signal connections
Debug versions should be done on standard 100mil pitch headers and jumpers
Flight versions should copy Pixhawk connectors whenever possible
This is for UART/I2C/SPI/ etc
Specific components will follow manufacturer recommended connectors if we for sure want to support it
i.e. the VectorNav VN-300 has it’s own connector we should just use since we are going to use this component on our system for sure!
If all the above do not offer adequate specification for a low voltage signal connector we will defer to automotive and marine standards and document here
LED’s
For realism, we will have regular Nav lights on the dirty 5V or 12V rail, as well as a green PAX aboard light that is on a 12V or 5V relay controlled by ZP.
Custom Hardware Mounting Hole Specification
For general custom EE flight PCBAs going forward on ground station and aircraft we will follow this mechanical mounting hole specification:
M3 - Any PCBA with area exceeding 2500 mm^2
3.400mm hole diameter (0.1mm tolerance)
6.000mm annular ring diameter
M2 - Any PCBA with area exceeding 750mm^2 and less than 2500mm^2
2.400mm hole diameter (0.1mm tolerance)
4.200mm annular ring diameter
No Mounting Holes - Any PCBA with area less than 750mm^2
No mounting holes will be present on board of this size.
All Mounting Holes will follow:
Electrically not connected to the PCBA (frame is ideally floating potential)
Eight vias (plated drills) placed evenly in the annular ring (in whichever drill size is used on the board (so effectively left to EE in charge to decide on via size)) for mechanical stiffness.
Electrical components and electrically pads should be at least 1mm away from the annular ring to avoid damaging the PCBA when mechanically bolting the board.
Groundside Architecture
Mandatory Hardware
Two RadioMaster TX16s Mk II Radios will be linked together using their trainer ports. One radio, serving as the “master”, will use a TBS Tracer system as a short relay to the RFD900x, connecting only a PPM or SBUS signal wire.
Any power that must be provided to the groundstation will use Turnigy 3s 4000mah nano-tech batteries. Any cooling fans will be noctua 40x10mm 5v 3 pin fans unless mech or ee requests otherwise.
Telemetry & Control
Telemetry will be provided via RFD900x, with the stock antennas mounted >20cm apart. There will be a USB cable which allows direct connection to the groundstation computer. There may need to be additional power supplied to the RFD900x to allow full power operation, and if such is the case it is possible to use XBEES in transparent serial mode instead of a USB cable, allowing the antenna to be moved further away. The RFD900 may require active cooling, so mech to add design that allows a fan to be attached (zipties are effective solutions).
Control will be provided using a TBS Tracer module, TX in the controller and RX outputting PPM or SBUS wired into the respective pin on the RFD900. There will be no downlink over TBS Tracer (i.e., no telemetry from the TBS Tracer). Wires from the rfd900 harness will be soldered directly to the TBS Tracer, providing power, signal, and gnd connections. It is important that the tracer and it’s antennas & wires are placed in a safe position where it cannot easily short and/or become disconnected or damaged.
Video
There will be 2 major components to the video system, one is the video relay and the other is the video receive devices. The video relay handles the transition between low frequency (1.3GHz) analog video into 5.8 GHz analog video. This video relay system will exist on a unique video relay tower, which houses the 1.3ghz antenna (singularity 1280), the 1.3ghz VRX, as well as the 5.8 GHz VTX and the respective antenna. Note that the VRX outputs video in an RCA format, and this will need to be spliced to solder pads or 2.54mm pitch pins on the VTX. The singularity 1280 must also be mounted so that the null zone is vertical.
If the 5.8 VTX were to be the Rush Tank Race II, then the antenna would be a u.fl terminated rush cherry w/long stem. If the 5.8 VTX were to be an AKK TS832, then the antenna would be an SMA terminated rush cherry w/stem. EE to provide clarity on whether or not adapters are needed. Both VTX will take signal from the video receiver, and share common VBatt & GND where VBatt is a 3S voltage. This VTX will be paired with the VRX, and can either be mounted on a tripod or a tall PVC pipe. This VTX may also require some degree of active cooling, consider how a fan may be mounted.
User endpoint Video Devices
All remaining VRX devices operate at 5.8 GHz, this includes:
pilot FPV goggles
FPV monitor
5.8 → USB receiver chain
Pilot FPV goggles are up to descrition of the pilot, and will be provided RHCP polarized stubs or stems depending on preference. These goggles will likely need 3s power. EE to determine how they receive power and what connecters sneed to be made. We will likely try and record the flight using the FPV goggles using the internal DVR function of the EMAX Transporter 2. Pilots may choose to use their own goggles, in which case the emax will use stock dipole antennas and function the same as a 5.8 GHz Monitor.
The FPV Monitor will likely use stock dipole antennas, but allow flight engineer to monitor FPV footage in real time along with the pilots. Currently, one monitor has a 2pin JST to XT60 adapter, EE to verify functionality and determine whether or not to make more. The FPV Monitor is capable of an RCA output, which means that it can be used with an RCA → USB adapter. EE To verify we have enough RCA cables in the right direction to operate in this mode. Theoretically, you could have one 5.8 Monitor away from the flightline for the rest of the team to view with. Up to you guys GG it just needs power.
There will also be a dedicated 5.8 GHz Video Receiver, currently we have an RC832 module, but any generic 5.8 GHz Receiver will work. This receiver can either output RCA, which will be adapted to a USB format to be used as a webcam on a PC, or it can output in a USB format directly. This video feed will be fed into the groundstation computer to allow for landing pad detection, or to allow recording of the flight.
Optional Hardware
Optional hardware typically requires the use of ZP with custom telemetry.
Tracking Antenna
The antennas will use directional antennas to improve connectivity with the drone, and must be placed as far apart and as high up as possible. They can be mounted on poles, and stakes may be driven into the ground with guy-lines to keep them upright (much like regular 5G antennas). Grounding wires can be driven into the ground as well. The towers should be as far apart as possible (one may have to be behind the tent and one in front of the tent - hence why it is important to get them to be able to go as high as possible), so that we have minimal interference. Even though we’re using different frequencies, they are still close to each other and notch filters may help significantly in signal quality, as will antenna separation. Antenna Towers should support fully tethered & fully untethered operation.
Each tower will have a: Nucleo, IMU, GPS, antenna all mounted on the panning & tilting head. This pan/tilt head should be able to track a drone flying ~ 70km/h at a 50m radius away while maintaining accuracy within 15 degrees of the center of a drone at a max range of 7km away. Mounted on the tracking antenna (but perhaps not on the moving head) of the antenna may be signal boosters, signal relays, excess wires, wire splitters, power, etc.
Tethered Operation
In the event of tethered operation, towers will have a USB Link from the Nucleo boards to the GSPC, as well as a set of coaxial cables (or a single one in non-diversity operation) to the modem located within the GS enclosure. Power may be supplied along a custom cable, but all of the cables running to the tower should be wrapped up and terminate together with clearly labelled interfaces on the GS enclosure.
Untethered Operation - not strictly necessary?
The towers should be able to run self-supported and disconnected from the rest of the system (including no power) for a minimum of 40 minutes. In the event that we want the towers to be running fully untethered, the Nucleos will communicate with the PC using low-power XBEES@ 2.4ghz instead of the USB tether, and we will use a PPM Relay with lower power 2.4GHz TBS Tracer rc system to communicate from the controller to T_telem. It is also possible for T_telem to be set up as a mesh where there is permanently a third nucleo inside the gs_enclosure, which will be linked to the main antenna on T_Telem that allows data to be passed through from airside to T_Telem to GSPC. A 5.8GHz video relay will be used to distribute video from T_Vrx to the pilot goggles, as well as the DVR → GSPC. Individual batteries will be provided to each tower, but these should support the system for a minimum of 1hr.
GS_SW
The software on the Ground Station inscludes the GUI, as well as all the backend processing for receiving/sending telemetry data. This is built entirely by the CV Subteam.
Telemetry TX/RX
messaging formats will be defined in the software architecture section.
The GSPC will receive from the RFD900x as a serial stream. This will be processed by the GS_SW before being displayed on the gui and passed to the tracking tower nucleos.
The tracking tower nucleos will also interface with the computer as serial streams (either xbee or wired). Care will have to be taken to ensure there is no crosstalk between them.
GSPC will send to the aircraft using the rfd900 serial communications port.
GUI
The gui should allow for the user to see the aircraft status, aircraft track, path, waypoints, and other relevant flight data listed in https://uwarg-docs.atlassian.net/wiki/spaces/CV/pages/2075820129 .
The GUI will also allow the pilot to edit waypoints & command the aircraft to takeoff/land in certain modes. The Aircraft shall operate in GPS_Hold mode when being operated remotely from the groundstation.
Remote Piloting
The command of the aircraft will be done by the pilot with their choice of either a dedicated set of FPV Goggles or Monitor, connected to the VRX either by 5.8 relay or direct by split rca. The controllers used will be TX16s MKII models, and a ppm relay or output converter will be provided on a frequency other than: 900, 1.2, 1.3, 2.4, 5.8. this means we need to buy more dragonlink modules?
Two controllers will be linked together, with one controller being the “master” using the trainer port. This means that if one pilot is unable to continue flying, the second pilot can takeover simply by hitting the switch. CC: @Megan Spee confirm this is ok w/u at comp?
Software Architecture
This section will discuss the computers involved, before then diving into communication architecture as well as messaging formats, different flight modes, and fail-safe contingencies.
Note that in our architecture, all communication from and to the ground is going to go through either the RFD900x, or the VTX module.
The computers
There will be three computers onboard the 2022-2023 competition frame <name>. Each of these has a dedicated purpose and will function in a specific subset of our flight route.
PX5
The PX5 Will be set as a real time backup, as well as potentially act as a sensor readout. The PX5 has 3 IMUs, 2 temperature calibrated barometers, and will run it’s own sensor fusion algorithms and can act as a backup source of information for position, and a primary source of altitude information. It does not strictly need to placed at COM since GQC can correct for this. @Dhruv Upadhyay
When the PX5 is acting as a real-time backup, the PX5 will be communicating to and from ZP using 3 PPM wires. 1 PPM will be from ZP → PX5, acting as 8 controller inputs, while 2 PPM will be from PX5 → ZP, acting as direct motor outputs. This retains ZPin control of communications and other functions of the drone, but allows for failsafe in case of a compute error inside of ZeroPilot’s own attitude management system. The PPM from PX5 will either be encoded directly onboard, or the PM outputs from px5 will be converted externally by PWM → PPM converters.
Communication with barometer data may occur over a serial link such as UART, depending on UART availability on ZP.
The communication to ZP will include the following:
arm/disarm signal (arming before we takeoff for no errors)
output enable/disable signal (so that ArduPilot doesn’t freak out)
4 channels of input request of where to fly to (ArduPilot will fly in GPS mode).
1 channel configuration plane/quad/hybrid
1 channel autonomous land/takeoff/cruise.
Jetson TX2
The Jetson will handle geolocation of landing pads, as well as the final landing-approach sequence. ZP will request information from the Jetson when ZP is ready to begin the landing sequence, and Jetson will return data on which direction to fly in. Inertial flight < 1s closed loop should be possible with centimeter accuracy. Thus, the Jetson handles the search pattern for the landing pad, as well as the process of centering the drone over the landing pad. Once landing has begun, ZP will no longer request data from the Jetson.
ZeroPilot
ZeroPilot will handle all of the inter-computer communications, as well as the air-ground communications, path planning for flying through waypoints, attitude management, as well as gathering sensor information and relaying that to other components. It is the primary driver of everything on the drone.
Flight Stages
We can break the autonomous flight modes down into: Boot, Disarmed, Ground Ops, Takeoff, Cruise, Search, Landing, Operator Override. In each of these modes, the software will interact differently to accomplish the tasks that it wants. It is important to note that at competition, the drone should be able to go from boot → ground ops with user input (physical drone arm, controller arm, software arm), and then it should be able to fly autonomously for the rest of the competition (including going between ground ops and flight).
Operator Override: This is the only mode where user inputs will translate directly to the motion of the drone. In all other modes, switches & buttons from the user may configure the drone to move to certain locations, but operator override gives the pilot the opportunity to control the control surfaces & attitude of the drone directly.
Boot
During the boot sequence, all sensors should be initialized & calibrated if required. connection between GS ↔︎ Drone should be initialized and confirmed. Any errors should be detected during this sequence and dealt with accordingly. This stage should be able to be reached using a Communications (comms) Emulator. The drone may need to be power cycled when going from comms emulator to RF comms. Comms emulator should verify all systems OK, and allow us to run certain diagnostic tests while on the ground (orientation, sensors, GPS, etc) in the absence of Radio Frequency control (e.g. Radio silence during competition).
Disarmed
In this mode, ALL components are disarmed. This means the drone is disarmed, the controller is disarmed, and the GS_SW is disarmed. All three must become armed for us to move out of disarmed move.
In this state, all systems should be in low power mode in order to prevent overheating. To arm the drone, the following process should be followed:
Arm the hardware. During this step, the hardware will ensure that everything is proper and the drone is fit for takeoff
Arm the controller. During this step, the pilot & flight crew should verify that they are ready for takeoff & flight.
Arm the software. During this step, the software should be checking to make sure that necessary links are established and ready to kick into effect.
Once all conditions are met, the drone will go into ground Ops.
Ground Ops
This is a mode where the drone is armed, the props are unable to spin (for safety) and systems can be in a high power mode. No arming is necessary to leave ground ops mode - it is purely a software distinction between being on the ground and in the air. It can let as accomplish things such as hot swapping batteries, landing & loading passengers (by lighting up the PAX ABOARD) light, etc. We leave this here so that there can be future expansion as well.
User Flight Mode: Operator Override
At any point, the remote pilot can override the system and control the drone in GPS, LEVEL, or ACRO (if the quad is in fixed wing mode).
Autonomous flight mode: Takeoff
Once the takeoff command is given, ZPSW or the PX5 will take the drone from the ground to a steady height in the air. The drone will hover in the air until it receives the ACK signal from GSSW saying that telemetry & vtx are OK (making sure that tracking antennas are working). Once it receives the ACK Signal, the drone will return ACK_Confirm wait for GS_SW to send a list of waypoints and then enter into cruise mode. Takeoff mode is purely ZP based. We expect GS_SW to send a list of waypoints before we liftoff from the ground.
Should an error occur during takeoff, the drone will land itself. Should an error occur when the drone is in the air, user override can be provided to bring it into cruise if desired, or the drone will land itself within 2 minutes. is this a reasonable amount of time to debug?
Autonomous flight mode: Cruise
During cruise, the drone will continually send back heartbeat, telemetry, and position data. In cruise mode, the primary decision makers are ZP & GS_SW. Should a re-route be needed, GS will send the remaining waypoints for the rest of the route, including waypoint ID=0 (GS’s knowledge of the current position of the drone).
Waypoints
A waypoint is a GPS coordinate paired with an ID number. The ID Number describes the sequence in which the drone is to fly waypoints. ZP will string together all the waypoints to create a flight path, where the final waypoint is the “hover” point and the transition to Search mode.
GS will send updated waypoints for the remainder of the route on a reroute, with waypoint ID=0 being the GS's knowledge of current position of the drone. This means that on a missed communication cycle, or on an updated diversion response, ZP will be able to dynamically re-route from the last known position of the drone to the next target waypoint without missing a waypoint since it can understand which waypoints it wants to hit and which waypoints it wants to skip.
Telemetry Data
Telemetry data consists of:
motor % values
Setpoints from the controller
current flight plan
attitude
battery voltages
sensor readouts
@Mihir Gupta anything else?
GPS mode
The operator can override GS_SW to send a new list of waypoints for a custom route. ZP continues to directly pilot the drone in this mode. Once the drone reaches the final waypoint, it transitions to Search mode as normal.
Autonomous flight mode: Search
When ZP has arrived at the last waypoint and there are no remaining waypoints to travel to, ZP will request from the Jetson where to go. During the flight, the Jetson will be continually receiving position packets from ZP, and so it should be able to correlate known landing pad locations to waypoints as we fly over them. At the final waypoint, the Jetson will either direct ZP in a relative direction (e.g. 4m forward, 2m left) if it sees the landing pad, or it will build a spiral search pattern and direct ZP’s movement until it can see the landing pad. See [CV Search] for technical details.
All direction commands sent to ZP are identical and include any direction in 3D space. The Jetson is responsible of keeping track of what general locations have been swept over using the position data, which includes altitude from the barometer or rangefinder.
Autonomous flight mode: Landing
Once the Jetson determines a suitable landing location, it will direct the drone to be centered above the landing pad and then drop the altitude to 2m above the landing pad in a controlled descent. At that point, if Jetson sends a message to ZP acknowledging the position is good to land, ZP will use a variety of sensor fusion algorithms & the optical flow sensor to descend vertically onto the pad. Auto-Land will be aborted after 3 failed communication cycles. At this stage, the drone shall return to a pre-determined height wherein landing requests will continue
Flight Control Modes
There will be a few distinct flight modes, each of which handles a portion of the flight. In each flight mode, the drone will process the controls differently.
GPS
GPS mode means that the drone will fly to a position that you specify. This can either be a GPS coordinate, or it could be relative coordinates that the drone well then rest at. This is how waypoints will be handled, and this is likely how most of the flight will be conducted.
LEVEL
LEVEL Mode means that the drone will self stabilize, but it will continue flying in the direction that you specify. Generally, this means that stick inputs will translate directly into a correspondent angle on the aircraft. This is likely how pilot manual flying will work.
ACRO
ACRO mode means that the controls control rate of rotation. It is unlikely that we will ever need to use this mode with a quadcopter, but it is possible that we will use this mode when doing an emergency takeover of a fixed wing aircraft to put it into a glide slope.
Communication
Communication between all devices will follow a standardized message format over UART (or serial) with a custom payload (so that is, retaining the regular UART start, parity, stop bits). See [UART] for more information.
Communication managers on each submodule should be responsible for decoding the incoming packets. We generally follow the HLDC frame protocol, which has the following structure:
Name | Size |
|
---|---|---|
Flag | 1 Byte | starting byte for new message |
Length | 2 Bytes | Length of message (in bytes), including Type, Info, and CRC |
Type | 1 byte | type of the message. See Indicates where data comes from and where it is meant to go. |
Info | n bytes | one of the packets associated with the datatype struct. |
CRC | 4 bytes | CRC32 Val. |
Datatype Structs
Please see https://uwarg-docs.atlassian.net/wiki/spaces/ARCHS22/pages/2131329241 for defined datatype structs, they have been moved. Note that each struct has an associated internal number that tends to be used in our diagrams.
ZP-Jetson Communication
ZP-Jetson communication and states are defined here: https://uwarg-docs.atlassian.net/wiki/spaces/ARCHS22/pages/2182479901
Logging on ZP
Logging will be done using an SD card. It will either be on an SPI-Based carrier board or using SDMMC on the L5 pins directly. The former will be used if we fly on a nucleo, the latter will be used if we fly on zp.
@Stanley Tang maybe add some more info on how logging might work?
Logging on Jetson
Log data on the Jetson will be recorded to the SD card containing the operating system.
Deployment Milestones
Fall 2022
ZP flying on ACRO mode fixed wing & LEVEL mode quad
ZP communicating with ground fully
Sensors ready to work
!?!?!?!?!??!?!?!
Nov 28: initial frame delivery & initial software delivery
Dec 20: See software-hardware integration, put in orders for everything that we will need for the next 4 months.
Winter 2023
Systems Integration Begins MID JANUARY
Competition Mock Flight MID FEBRUARY (maybe reading week or smth)
this is a hard deadline for software/hardware to be finalized. Past this point, we should stop development of new things and work on fixing / characterizing current things.
Multiple airframes ready mid-march
each airframe should be characterized and tuned. Pilots should be training on some of these models.
Action Items
Action | Description | Owner | Due date | Jira ticket | |
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1 | Oct 21, 2022 | ||||
2 |
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Test Airframes
Cornflakes
Frosted Flakes
Wiring Diagram
^ quad H motor layout
fmu ports connect to escs for data. ports 1-5 connect to motors 4, 1, 2, 3, 5. in that order.
References and documentation
How to use RFD900X: https://uwarg-docs.atlassian.net/l/cp/LPn8hwCv
VN-300 Rugged pinout: 2023-03-26 - VN-300 Rugged Harness
ZeroPilot Software ZeroPilot 3.0 Architecture
[UART] https://uwarg-docs.atlassian.net/wiki/spaces/EL/pages/2057502845
[Competition Design Outline] Competition Design Outline
[Competition Requirements] Competition Requirements
[CV Search] https://uwarg-docs.atlassian.net/wiki/spaces/CV/pages/2180186222
Version | Date | Comment |
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Current Version (v. 68) | 2023-08-03 14:46 | Olivia Markham |
v. 67 | 2023-07-05 20:20 | Amy Hu |
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v. 50 | 2023-02-15 19:14 | R D |
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v. 47 | 2023-02-11 01:36 | Anthony Luo |
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v. 32 | 2022-11-07 03:42 | Megan Spee |
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v. 9 | 2022-11-03 00:48 | Nathan Green |
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v. 1 | 2022-10-21 15:26 | Anthony Luo |