senior design partnership: amptraxx2
DESCRIPTION
Senior Design Partnership: AmpTraXX2. About Group 13. Matt Webb: Electrical Engineering Earl Maier: Electrical Engineering Minor in Mathematics Talitha Rubio: Electrical Engineering Computer Science Minor - PowerPoint PPT PresentationTRANSCRIPT
Senior Design Partnership: AmpTraXX2
About Group 13
Matt Webb: Electrical Engineering
Earl Maier: Electrical Engineering Minor in Mathematics
Talitha Rubio: Electrical Engineering Computer Science Minor
Daren Ruben: Electrical Engineering
25 Years of Alcorn McBride Experience
• Reliable• Network Configurable• Easily Scalable• Zero Maintenance• Very Flexible
Overview
Goal: Create a system that is capable of processing many channels of audio and distributing them over standard Ethernet networks to break-out boxes providing audio channel selection, signal level audio outputs, and a Class-D amplified output.
Application Example
• Annual events (Ex. Halloween Horror Nights)o Problem: New environments require changes in audio
distribution and filteringo Solution: Ethernet enables you to easily send signal to
anywhere within an existing network. Just plug in an AmpTraXX2 unit to add a new speaker. For environments that are being modified, select a different channel for sound playback on AmpTraXX2.
Current Practice
Improved Practice
DSP Unit Specifications
• Input and output stage DSP for 8 channels at 96KHz/24-bit• Input/Output routing matrix• Digital signal processing capabilities per channel
o Four EQ bands (Choose: Parametric, LPF, HPF)o Three topologies (Bessel, Butterworth, Linkwitz-Riley)o Dynamic Range Compression
• Dante Audio-over-Ethernet I/O• Web-based monitoring and controls
o View break-out box status and channel selectionso Change equalization, routing, and compressiono Check channel clip status o Optimized for iOS, Android, Windows Phone, BB
• Numerous physical inputs and outputs, 96KHz ADC/DAC• Integrated 4-port 1000Mbps Ethernet switch• Front Panel Controls• 1U Size
Break-out Box Specs
• Output any eight channels via Dante Audio-over-Ethernet• Stereo Class-D Amplifier (2x90W RMS @ 4Ohms)• Stereo signal output (Balanced, Unbalanced, S/PDIF)• Simple human interface to modify settings• Network monitored and controlled• Integrated 4-port 1000Mbps Ethernet switch• Compact Size (mount on rear of small speaker)
Connector Summary
• Centralized Audio DSP (All rear connections)o Stereo Unbalanced Inputs -- 2x RCAo Stereo Balanced Inputs -- 2x XLR Femaleo S/PDIF Input -- 1x RCAo Stereo Balanced Outputs -- 2x XLR Male o S/PDIF Output -- 1x RCAo 1Gbps Ethernet -- 4x RJ-45o Power (IEC 60320-1 C13)
• Amplified Break-Out Box (All rear connections)o Stereo Amplified Outputs -- 4x Binding Posts o Stereo Balanced Outputs -- 2x XLR Maleo Stereo Unbalanced Outputs -- 2x RCAo S/PDIF Output -- 1x RCAo Eurocon GPIO Pin – 16xo 1Gbps Ethernet -- 4x RJ-45o Power (IEC 60320-1 C13)
DSP Box
Breakout Box
DSP Signal Flow
BOB I/O Diagram
Software Diagram
UART
Dante Brooklyn II
• NDA required• Supports up to 16 audio channels per TDM• Supports Gigabit and 100 Mbps Ethernet• At 96kHz Sampling frequency we can have 32
bidirectional channels of audio.• Simplified configuration management. (Plug and play
network).• All audio devices on the network must be Dante
enabled.• Works with existing LAN networks• Up to 32 bit audio words• Redundancy in Ethernet input
A/D and D/A
Cirrus Logic Codec P/N CS42448
Features:• Six (6) 24-bit A/Ds• Eight (8) 24 bit D/As• Compatible with TDM• ADC/DAC 192 KHz
Sampling Rate• Digital Volume Control• I2C & SPI capable
Purpose:• Analog to Digital• Digital to Analog• Volume Control
Advantage:Eliminates the need for separate A/D and D/A.
Digital Routing
DIX 9211 (Digital Audio Interface Transceiver)
• Function: o Route the digital audio signal between the
CODEC and Brooklyn IIo Provide S/PDIF input and output
• DIX 9211 became a necessity when the decision was made to use the same PCB layout for both boxes.
Digital Routing
Class D-Amp
Abletec ALC0180 specifications:• 2x90 Wrms/4ohm @ 1% THD• 1x180 Wrms/8ohm bridged @
1% THD• 2x50 Wrms/8ohm @ 1% THD• Over current protection• Over temperature protection• Over voltage protection
Bridge Mono vs Stereo
User will control the amplifier stereo/bridge configuration via the user interface. The speaker connection to the amp will have to be changed manually.
•132KB of on chip full speed SRAM•CPU: up to 600 MHz•Core voltage: 0.8-1.3V, DPM•Useful ports: SPI, SPORT, TWI• Up to 48 peripheral control lines•Extra features atypical of signal processors•Real-time OS•Capable 16/32 bit operations•Sponsor-recommended part
Blackfin DSP Chip
μCLinux – Linux alternative adapted for MCUs.•Linux kernel: Built-in IP connectivity, reliability, portability, filesystems, free software•Under 300KB•Full Linux 2.6 features: API, multi-tasking, stability, drivers•Robust•Supports C/C++ applications•Using a real-time OS relieves developer of control coding
Real-Time OS
ALSA (Advance Linux Sound Architecture)•ALSA drivers provide audio functionality to the Linux OS.•Supports all types of audio interfaces: consumer sound cards to professional multi-channel interfaces•Simplifies application development and provides higher level functionality•Open-source•Linux community provides useful tutorials for driver development
ALSA Driver
Stellaris Microcontroller
Functions:• Monitor temperature and
amplifier status• Control CODEC and DIX• Control user interface
o Web Servero Screen
Requirements:• Support Ethernet• I2C and SPI capable• Large memory • >32KB Flash• Over 10 GPIO
LM3S8962:• 5-42 GPIO• UART• I2C and SSI capable• CAN and Ethernet
capable• 256KB memory• Inexpensive
Front PanelThe front panel will consist of• Newhaven Screen• Rotary Encoder• Select Button• Red/Green LED array for status (DSP Box only)• Blue LED for power• I2C expanders
Gigabit Ethernet Switching
• 1000Base-T Ethernet is required for maximum Dante channel counts
• IEEE 802.1 Audio-Video Bridging (AVB) switches preferredo Reserve network bandwidth for streaming mediao Shape traffic around streaming media
• Duties:o Provide Brooklyn II module with Ethernet (audio)o Provide Stellaris with Etherneto Provide two additional ports for daisy-chaining
Marvell 88E6350 Switch
• Very new Marvell part -- NDA required• 5 PHY + 7 MAC w/ GMII for Brooklyn II• AVB Compatible (802.1AS, 802.1Qat, 802.1Qav)
Dante Primary
Stellaris
Daisy-Chain
Dante Secondary
Daisy-Chain
Brooklyn II
Audio Clock Distribution
• Three audio clocks control ADC's, DAC's, and filteringo Master Clock -- Driven by Brooklyn II Module
Derive LM26003 switching frequency (384KHz) Derive 24.576MHz for DIX9211 Send to CODEC, DIX9211 auxiliary inputs
o Bit Clock -- Driven by Brooklyn II Module Send to Blackfin SPORT0, SPORT1 Primary+Secondary Send to CODEC, DIX9211 auxiliary inputs
o LR/Frame Clock -- Driven by Brooklyn II Module Send to Blackfin SPORT0, SPORT1 Primary+Secondary Send to CODEC, DIX9211 auxiliary inputs
Audio Clock Distribution
Audio Clock Distribution
TDM Audio Routing
TDM Audio Routing
Resistor Mux
The Resistor Mux allows for the DSP box and break-out box to be developed with the same PCB layout.
ConnectionsDSP BoxCODEC(A/D out) => BlackFinBlackFin => CODEC(D/A in)
Breakout BoxCODEC(A/D out) => BrooklynBrooklyn(out) => CODEC(D/A in)
Power Supply
AC -> DC Conversion 5V Switching Regulator
Power Supply
3.3V Switching Regulator LDO Regulators
User Interface
• Required Taskso Modify DSP settings (EQ, Compression)o Modify matrix routingo Assign/modify channel nameso Check clip/overflow statuso Monitor break-out box status on network
• Create great mobile device experienceo Write web apps using jQuery Mobileo "Native" app feelo Considerably less programming time
User Interface Web API
• Create communication interface between web interface and C code• Required actions:
o Get channel listing (name, status, numerical identifier)o Get equalization parameters (band, type, q, center freq, gain)o Get compressor parameters (threshold, ratio, attack, release, gain)o Get matrix routing (indexed by output number)o Get breakout box statuso Get overflow/clip statuso Rename channel (pass numerical identifier and new name)o Change matrix routing (pass output identifier, input identifier)o Change EQ params (pass channel identifier, all band params)o Change compressor params (pass channel identifier, all params)
User Interface Web API
• Utilize JavaScript Object Notation (JSON) for population of GUI data
• Requires JSON encoder in C -- had to write my own• LOTS of code and a rather large sudden amount of
memory usage• Examples:
o Compressor Parameters: ipaddress/a/o/3/compparams {"gain":2.0000,"threshold":10.0000,"ratio":1.5000, "attack":10.0000,"release":500.0000,"enable":1.0000}
o Channel List: ipaddress/a/i/chanlist [{"name":"ch01","active":1,"io":0,"num":2},{"name":"Ch2!","active":1,"io":0,"num":2}]
Stellaris/Blackfin API
• Create communication standard between Blackfin and Stellaris• Designed similar to instruction types for embedded processors• Multiple command types: Read, Write, Acknowledge, Notification• Read from BF: Investigate a DSP parameter or setting• Write to BF: Change a DSP parameter or setting• Acknowledge: Send a command back to Stellaris after write• Notification: Inform Stellaris of signal and clipping
Stellaris/Blackfin API
Read Value
Write Value
Acknowledgement
Notification
Audio Processing Flow
Filtering Types
• Besselo Create coefficient generator up to fourth order
• Butterwortho Implement algorithm to figure out even and odd
Butterworth coefficientso Allow for 1st, 2nd, 3rd, 4th order filterso Generate each section as biquad’s
• Linkwitz-Riley (defined by -6dB at cutoff frequency)o 2nd order -- 2 first order filters in cascadeo 4th order -- 2 second order butterworth filters in
cascade
Current Implementation
• Physical UI on Stellaris• Change IP, Netmask, Gateway• Change channel volumes
• Web UI on Stellaris• Rename channels• Change filter values and types in realtime
• DSP Filter Algorithms• IIR 1st and 2nd Order Butterworth and Bessel LPF/HPF• IIR Parametric equalizer
• Blackfin• UART Communication with Stellaris• Implements algorithms above
Budget
Questions?
Thank you!