Presentation is loading. Please wait.

Presentation is loading. Please wait.

To use the blackfin processor BF-533 to implement what we have learned about the blackfin processor. My approach for this project by : Input Audio will.

Published bySimon Patterson Modified over 8 years ago

Similar presentations

Presentation on theme: "To use the blackfin processor BF-533 to implement what we have learned about the blackfin processor. My approach for this project by : Input Audio will."— Presentation transcript:

1

2 To use the blackfin processor BF-533 to implement what we have learned about the blackfin processor. My approach for this project by : Input Audio will play throw 4 speakers and all LEDs will be turned off. PF8(once) : activate the IIR low pass filter, LED: 4 turn on (twice) : activate the FIR low pass filter. LED :4, 5 turn on PF9 (once) : activate the IIR High pass filter. LED :4,5,6,7 turn on (twice) : activate the FIR High pass filter. LED:4,5,6,7,8,9 turn on PF10: Activate / Deactivate the Mute function. LED :4,5,6,7,8,9

3 Input Audio will play throw 4 speakers and all LEDs will be turned off. EX_INTERRUPT_HANDLER(FlagA_ISR) { if (low==0 && high==0) { *pFlashA_PortB_Data=0x00; iChannel0LeftIn = iRxBuffer1[INTERNAL_ADC_L0]; iChannel0RightIn = iRxBuffer1[INTERNAL_ADC_R0]; iChannel1LeftIn = iRxBuffer1[INTERNAL_ADC_L1];//l iChannel1RightIn = iRxBuffer1[INTERNAL_ADC_R1]; Original(); iTxBuffer1[INTERNAL_DAC_L0] = iChannel0LeftOut; iTxBuffer1[INTERNAL_DAC_R0] = iChannel0RightOut; iTxBuffer1[INTERNAL_DAC_L1] = iChannel1LeftOut; iTxBuffer1[INTERNAL_DAC_R1] = iChannel1RightOut; }

4 Transfer function for IIR filter. we implement the Transfer function using the two formulas: Matlab Low pass filter frequencies : F stop = 5000 Hz F pass = 8000 Hz High pass filter frequencies : F stop = 1400 Hz F c = 2000 Hz Generate a Header file which include the filter coefficients.

5 Filter coefficient collapsed and corrupt every now and then since yesterday night. Redesign the filter in math lab and redo the coefficient. But it is not a permanent solution because the problem keeps coming back

6 pressing PF8(once): Activates IIR low pass filter. EX_INTERRUPT_HANDLER(FlagA_ISR) { if(*pFIO_FLAG_C == 0x0100) { *pFIO_FLAG_C = 0x0100; high=0; if(low<2) { low++; } else { low=0; }

7 EX_INTERRUPT_HANDLER(Sport0_RX_ISR) { if(low==1) { high=0; *pFlashA_PortB_Data=0x01; iChannel0LeftIn = iRxBuffer1[INTERNAL_ADC_L0]; iChannel0RightIn = iRxBuffer1[INTERNAL_ADC_R0]; iChannel1LeftIn = iRxBuffer1[INTERNAL_ADC_L1]; iChannel1RightIn = iRxBuffer1[INTERNAL_ADC_R1]; lowpassfilterIIR(); iTxBuffer1[INTERNAL_DAC_L0] = iChannel0LeftOut; iTxBuffer1[INTERNAL_DAC_R0] = iChannel0RightOut; iTxBuffer1[INTERNAL_DAC_L1] = iChannel1LeftOut; iTxBuffer1[INTERNAL_DAC_R1] = iChannel1RightOut; } PF8(once) continue:

8 pressing PF8(twice): Activates FIR low pass filter. EX_INTERRUPT_HANDLER(Sport0_RX_ISR) { if(low==2) { high=0; *pFlashA_PortB_Data=0x03; iChannel0LeftIn = iRxBuffer1[INTERNAL_ADC_L0]; iChannel0RightIn = iRxBuffer1[INTERNAL_ADC_R0]; iChannel1LeftIn = iRxBuffer1[INTERNAL_ADC_L1]; iChannel1RightIn = iRxBuffer1[INTERNAL_ADC_R1]; highpassfilter_FIR(); iTxBuffer1[INTERNAL_DAC_L0] = iChannel0LeftOut; iTxBuffer1[INTERNAL_DAC_R0] = iChannel0RightOut; iTxBuffer1[INTERNAL_DAC_L1] = iChannel1LeftOut; iTxBuffer1[INTERNAL_DAC_R1] = iChannel1RightOut; }

9 pressing PF9(ONCE): Activates IIR High pass filter. EX_INTERRUPT_HANDLER(FlagA_ISR) { if(*pFIO_FLAG_C == 0x0200) { *pFIO_FLAG_C = 0x0200; low=0; if(high<2) { high++; } else { high=0; }

10 EX_INTERRUPT_HANDLER(Sport0_RX_ISR) { if(high==1) { low=0; *pFlashA_PortB_Data=0x0f; iChannel0LeftIn = iRxBuffer1[INTERNAL_ADC_L0]; iChannel0RightIn = iRxBuffer1[INTERNAL_ADC_R0]; iChannel1LeftIn = iRxBuffer1[INTERNAL_ADC_L1]; iChannel1RightIn = iRxBuffer1[INTERNAL_ADC_R1]; HighpassfilterIIR(); iTxBuffer1[INTERNAL_DAC_L0] = iChannel0LeftOut; iTxBuffer1[INTERNAL_DAC_R0] = iChannel0RightOut; iTxBuffer1[INTERNAL_DAC_L1] = iChannel1LeftOut; iTxBuffer1[INTERNAL_DAC_R1] = iChannel1RightOut; } PF9 (once)continue:

11 pressing PF9(twice): Activates FIR High pass filter. EX_INTERRUPT_HANDLER(Sport0_RX_ISR) { if(high==2) //plays audio input through the high pass filter { low = 0; *pFlashA_PortB_Data=0x3f; iChannel0LeftIn = iRxBuffer1[INTERNAL_ADC_L0]; iChannel0RightIn = iRxBuffer1[INTERNAL_ADC_R0]; iChannel1LeftIn = iRxBuffer1[INTERNAL_ADC_L1]; iChannel1RightIn = iRxBuffer1[INTERNAL_ADC_R1]; lowpassfilter_FIR(); iTxBuffer1[INTERNAL_DAC_L0] = iChannel0LeftOut; iTxBuffer1[INTERNAL_DAC_R0] = iChannel0RightOut; iTxBuffer1[INTERNAL_DAC_L1] = iChannel1LeftOut; iTxBuffer1[INTERNAL_DAC_R1] = iChannel1RightOut; }

12 pressing PF10: Activates Mute function. EX_INTERRUPT_HANDLER(FlagA_ISR) { *pFIO_FLAG_C = 0x0400; if(mute<1) { mute++; } else { mute=0; } EX_INTERRUPT_HANDLER(Sport0_RX_ISR) { if(mute==1) { high=0; low=0; mute_b(); }

13 I got all other filters to work as expected in in this class. I re-design the IIR low pass many times since yesterday night and it continues to corrupt. Hopefully it will work during the demonstration. things I would change: If I have taken Signal and Systems I would be able to improve my filter and how they sound.

Download ppt "To use the blackfin processor BF-533 to implement what we have learned about the blackfin processor. My approach for this project by : Input Audio will."

Similar presentations

Microcomputer Systems I ECE 3551 MOHAMMED ALYAMANI Instructor: Dr. Kepuska.

Microcomputer Systems I ECE 3551 MOHAMMED ALYAMANI Instructor: Dr. Kepuska.
Mohammed Almajhad Final Project Dr. Kepuska. Intro My project idea is based on playing sound on different effects as we see these days. Also, adding a.

Mohammed Almajhad Final Project Dr. Kepuska. Intro My project idea is based on playing sound on different effects as we see these days. Also, adding a.
Unit 9 IIR Filter Design 1. Introduction The ideal filter Constant gain of at least unity in the pass band Constant gain of zero in the stop band The.

Unit 9 IIR Filter Design 1. Introduction The ideal filter Constant gain of at least unity in the pass band Constant gain of zero in the stop band The.
Lab. 1 – Earlier Tasks. Needed by both application and demonstration lab. streams For more details – see the Lab. 1 web-site There will be a 20 min prelab-quiz.

Lab. 1 – Earlier Tasks. Needed by both application and demonstration lab. streams For more details – see the Lab. 1 web-site There will be a 20 min prelab-quiz.
Over-view of Lab. 1 For more details – see the Lab. 1 web-site There will be a 20 min prelab quiz (based on Assignment 1 and 2) at the start of the lab.

Over-view of Lab. 1 For more details – see the Lab. 1 web-site There will be a 20 min prelab quiz (based on Assignment 1 and 2) at the start of the lab.
Lab. 1 – Task 1 to 4 details For more details – see the Lab. 1 web-site There will be a 20 min prelab-quiz (based on Assignment 1 and 2) at the start of.

Lab. 1 – Task 1 to 4 details For more details – see the Lab. 1 web-site There will be a 20 min prelab-quiz (based on Assignment 1 and 2) at the start of.
Over-view of Lab. 1 For more details – see the Lab. 1 web-site There will be a 20 min prelab quiz (based on Assignment 1 and 2) at the start of the lab.

Over-view of Lab. 1 For more details – see the Lab. 1 web-site There will be a 20 min prelab quiz (based on Assignment 1 and 2) at the start of the lab.
DSP Implementation of a 1961 Fender Champ Amplifier James Siegle Advisor: Dr. Thomas L. Stewart March 11, 2003.

DSP Implementation of a 1961 Fender Champ Amplifier James Siegle Advisor: Dr. Thomas L. Stewart March 11, 2003.
Later tasks of Lab. 1 For more details – see the Lab. 1 web-site There will be a 20 min prelab quiz (based on Assignment 1 and 2) at the start of the lab.

Later tasks of Lab. 1 For more details – see the Lab. 1 web-site There will be a 20 min prelab quiz (based on Assignment 1 and 2) at the start of the lab.
Professor: Dr Kepuska Presented by Kyle Farnum. Audio Manipulation through utilizing three types of filters: Low-pass filters Band- pass filters High-

Professor: Dr Kepuska Presented by Kyle Farnum. Audio Manipulation through utilizing three types of filters: Low-pass filters Band- pass filters High-
Joshua “Rock Star” Jenkins Jeff “Tremolo” Smith Jairo “the boss” Rojas

Joshua “Rock Star” Jenkins Jeff “Tremolo” Smith Jairo “the boss” Rojas
DSP Term Project By: Ashley Downs And Jeff Malen By: Ashley Downs And Jeff Malen.

DSP Term Project By: Ashley Downs And Jeff Malen By: Ashley Downs And Jeff Malen.
Graphic Equalizer Table By Jose Lerma. Main Idea The main idea of this table is to display the frequencies of any sound or audio input, either by microphone.

Graphic Equalizer Table By Jose Lerma. Main Idea The main idea of this table is to display the frequencies of any sound or audio input, either by microphone.
Sub-band Mixing and Addition of Digital Effects for Consumer Audio ELECTRICAL & ELECTRONIC ENGINEERING FINAL YEAR PROJECTS 2012/2013 Presented by Fionn.

Sub-band Mixing and Addition of Digital Effects for Consumer Audio ELECTRICAL & ELECTRONIC ENGINEERING FINAL YEAR PROJECTS 2012/2013 Presented by Fionn.
0 - 1 © 2010 Texas Instruments Inc Practical Audio Experiments using the TMS320C5505 USB Stick “FIR Filters” Texas Instruments University Programme Teaching.

0 - 1 © 2010 Texas Instruments Inc Practical Audio Experiments using the TMS320C5505 USB Stick “FIR Filters” Texas Instruments University Programme Teaching.
EE513 Audio Signals and Systems Digital Signal Processing (Systems) Kevin D. Donohue Electrical and Computer Engineering University of Kentucky.

EE513 Audio Signals and Systems Digital Signal Processing (Systems) Kevin D. Donohue Electrical and Computer Engineering University of Kentucky.
Volume. 1-the idea of the program is to increase, decrease the volume. 2-the program does the following: A-PF8:decrease the volume B-Pf9:increase the.

Volume. 1-the idea of the program is to increase, decrease the volume. 2-the program does the following: A-PF8:decrease the volume B-Pf9:increase the.
UNIT-5 Filter Designing. INTRODUCTION The Digital filters are discrete time systems used mainly for filtering of arrays. The array or sequence are obtained.

UNIT-5 Filter Designing. INTRODUCTION The Digital filters are discrete time systems used mainly for filtering of arrays. The array or sequence are obtained.
1 Lab. 4 Sampling and Rate Conversion  Sampling:  The Fourier transform of an impulse train is still an impulse train.  Then, x x(t) x s (t)x(nT) *

1 Lab. 4 Sampling and Rate Conversion  Sampling:  The Fourier transform of an impulse train is still an impulse train.  Then, x x(t) x s (t)x(nT) *
EZ-Additive Synthesizer By Max Bastien 12/14/07. Problem Statement Mystery of keyboards reproducing a wide range of sounds from any particular instrument.

EZ-Additive Synthesizer By Max Bastien 12/14/07. Problem Statement Mystery of keyboards reproducing a wide range of sounds from any particular instrument.

Similar presentations

Ads by Google