Difference between revisions of "DsPIC30F 5011 Development Board"

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This project aims to provide the development tools for building a [[Multi-purpose_Embedded_System | multi-purpose MCU board]]. Description is based on Microchip dsPic33FJ256GP506 (was dsPic30F5011), but information provided in this wiki may give useful directions for developing similar embedded systems with different platforms.
 +
 
==Introduction==
 
==Introduction==
  
===Features of dsPIC30F5011===
+
===Features of dsPic33FJ256GP506===
*2.5 to 5V
+
*3.0 to 3.3 V
*Up to 30MIPs
+
*Up to 40 MIPs
*High current/sink source I/O pins: 25mA
+
*Maximum current sink/source for I/O pins: 4 mA
 +
*16-bit arithmetics
 
*DSP Instruction Set
 
*DSP Instruction Set
 
*Dual programming techniques: ICSP and RTSP
 
*Dual programming techniques: ICSP and RTSP
*UART: up to 2 modules
+
*Memory
*I<sup>2</sup>C: up to 1Mbps
+
**256&nbsp;KB flash (86K instructions)
*10-bit A/D, 1.1 Msps
+
**16&nbsp;KB RAM (incl. 2&nbsp;KB DMA RAM)
*12-bit A/D, 200 ksps
+
**No EEPROM
*66Kb flash, 4Kb RAM, 1Kb EEPROM
+
*Communications ports
*No DAC
+
**UART
 
+
**I<sup>2</sup>C: up to 1&nbsp;Mbit/s
===Web Page===
+
**SPI
*[http://www.microchip.com/stellent/idcplg?IdcService=SS_GET_PAGE&nodeId=2529&param=en024856 Microchip Official Website]
+
*ADC
 
+
*10-bit A/D, 1.1 Msps
===Forum===
+
*12-bit A/D, 500 ksps
*[http://direct.forum.microchip.com/default.aspx Microchip]: Official forum by Microchip
+
*No DAC (PWMs only)
**[http://direct.forum.microchip.com/tt.aspx?forumid=49 MPLAB ICD 2]: Subforum on ICD 2 programmer
+
*Pin-to-pin compatible with other dsPICs
**[http://direct.forum.microchip.com/tt.aspx?forumid=57 MPLAB IDE]: Subforum on IDE
+
{| border="1" cellspacing="0" cellpadding="5"
**[http://direct.forum.microchip.com/tt.aspx?forumid=101 MPLAB C30 Compiler, ASM30, Link30 forum]: Subforum on C compiler. Refer to [http://ww1.microchip.com/downloads/en/DeviceDoc/C30_Users_Guide_51284e.pdf MPLAB C30 C Compiler User's Guide] Chapter 3
+
|+ Comparison between different dsPICs
**[http://direct.forum.microchip.com/tt.aspx?forumid=153 dsPIC30F Topics]: Subformum on dsPIC30F
+
! dsPic !! *Price<br>US$ !! MIPs
 
+
! Flash<br>(kB)!! RAM<br>(kB) !! EEPROM<br>(kB)
*[http://www.gnupic.org/ GNUPIC]: Discussion on PIC in Linux Systems
+
! I/O !! ADC<br>12-bit !! IC !! OC !! Motor<br>Ctrl !! Timers
**[http://www.linuxhacker.org/cgi-bin/ezmlm-cgi?1:dds:5443#b Debian]
+
! QEI !! UART !! SPI !! I2C !! CAN !! Codec
 +
|-
 +
| 33FJ256GP506 || 6.11 || 40
 +
| 256 || 16 || 0
 +
| 53 || 18 || 8 || 8 || 0 || 9x16bit<br>4x32bit
 +
| 0 || 2 || 2 || 2 || 1 || 1
 +
|-
 +
| 33FJ128GP206 || 4.62 || 40
 +
| 128 || 8 || 0
 +
| 53 || 18 || 8 || 8 || 0 || 9x16bit<br>4x32bit
 +
| 0 || 2 || 2 || 1 || 0 || 1
 +
|-
 +
| 33FJ128GP306 || 4.81 || 40
 +
| 128 || 16 || 0
 +
| 53 || 18 || 8 || 8 || 0 || 9x16bit<br>4x32bit
 +
| 0 || 2 || 2 || 2 || 0 || 1
 +
|-
 +
| 33FJ128GP706 || 5.49 || 40
 +
| 128 || 16 || 0
 +
| 53 || 18 || 8 || 8 || 0 || 9x16bit<br>4x32bit
 +
| 0 || 2 || 2 || 2 || 2 || 1
 +
|-
 +
| 33FJ128MC506 || 4.97 || 40
 +
| 128 || 8 || 0
 +
| 53 || 16 || 8 || 8 || 8 || 9x16bit<br>4x32bit
 +
| 1 || 2 || 2 || 2 || 1 || 0
 +
|-
 +
| 33FJ128MC706 || 5.38 || 40
 +
| 128 || 16 || 0
 +
| 53 || 16 || 8 || 8 || 8 || 9x16bit<br>4x32bit
 +
| 1 || 2 || 2 || 2 || 1 || 0
 +
|-
 +
|}
 +
<nowiki>*</nowiki>For reference only, subject to change
  
 +
===Forums===
 +
*[http://forum.microchip.com/ Microchip]: Official forum by Microchip
 +
**See MPLAB ICD 2, MPLAB IDE, MPLAB C30 Compiler, ASM30, Link30 forum, dsPIC30F Topics, dsPic33 topics
 
*[http://www.htsoft.com/forum/all/ubbthreads.php/Cat/0/C/6 HI-TECH Software Forum]: Discussion on dsPICC, a C compiler developed by HI-TECH
 
*[http://www.htsoft.com/forum/all/ubbthreads.php/Cat/0/C/6 HI-TECH Software Forum]: Discussion on dsPICC, a C compiler developed by HI-TECH
 
+
*[http://sourceforge.net/forum/forum.php?forum_id=382005 FreeRTOS Real Time Kernel]: Open Discussion and Support on FreeRTOS
*[http://piclist.com/techref/piclist/index.htm PICList]: Discussion on older PIC systems (not dsPIC)
+
*[http://www.nabble.com/MicroControllers---GNUPIC-f2057.html Nabble]: MicroControllers - GNUPIC
 
 
*[http://groups.google.com/group/pickit-devel PicKit]: Discussion on PICkit/PICkit 2 programmers
 
  
 
===References===
 
===References===
*dsPIC30F
+
*dsPIC33F
**[http://ww1.microchip.com/downloads/en/DeviceDoc/70043F.pdf Family Overview]
+
**[http://www.microchip.com/stellent/idcplg?IdcService=SS_GET_PAGE&nodeId=2573 dsPIC33F Family Reference Manual Sections]
**[http://ww1.microchip.com/downloads/en/DeviceDoc/70046E.pdf Family Reference Manual]: Contains detailed descriptions on dsPIC30F register definitions and example codes
+
**[http://ww1.microchip.com/downloads/en/DeviceDoc/70286C.pdf dsPIC33FJXXXGPX06/X08/X10 Data Sheet]
**[http://ww1.microchip.com/downloads/en/DeviceDoc/70116F.pdf 5011 Data Sheet]
+
**[http://ww1.microchip.com/downloads/en/DeviceDoc/80306E.pdf dsPIC33FJXXXGPX06/X08/X10 Rev. A2/A3/A4 Silicon Errata]
**[http://ww1.microchip.com/downloads/en/DeviceDoc/70102G.pdf Flash Programming Specification]
+
**[http://ww1.microchip.com/downloads/en/DeviceDoc/70152G.pdf Flash Programming Specification]
**[http://ww1.microchip.com/downloads/en/DeviceDoc/70157B.pdf Programmer Reference Manual]
 
 
*ICD2 Programmer
 
*ICD2 Programmer
**[http://ww1.microchip.com/downloads/en/DeviceDoc/51331B.pdf ICD2 User's Guide]
+
**[http://ww1.microchip.com/downloads/en/DeviceDoc/51331C.pdf ICD2 User's Guide]
 
*MPLAB
 
*MPLAB
 
**[http://ww1.microchip.com/downloads/en/DeviceDoc/51519B.pdf MPLAB IDE User's Guide]
 
**[http://ww1.microchip.com/downloads/en/DeviceDoc/51519B.pdf MPLAB IDE User's Guide]
 
*C30 Compiler
 
*C30 Compiler
**[http://ww1.microchip.com/downloads/en/DeviceDoc/C30_Users_Guide_51284e.pdf MPLAB C30 C Compiler User's Guide]: Contains commands for using pic30-elf-gcc
+
**[http://ww1.microchip.com/downloads/en/DeviceDoc/C30_Users_Guide_51284e.pdf MPLAB C30 C Compiler User's Guide]: Contains commands for using pic30-elf-gcc
 
**[http://ww1.microchip.com/downloads/en/DeviceDoc/16bit_Language_Tool_Libraries_51456c.pdf 16-bit Language Tools Libraries]: Contains summaries and examples of using DSP libraries, standard C libraries and device libraries
 
**[http://ww1.microchip.com/downloads/en/DeviceDoc/16bit_Language_Tool_Libraries_51456c.pdf 16-bit Language Tools Libraries]: Contains summaries and examples of using DSP libraries, standard C libraries and device libraries
 
**[http://ww1.microchip.com/downloads/en/DeviceDoc/Asm30_Link_Util_51317e.pdf MPLAB ASM30, MPLAB LINK30 and Utilities User's Guide]
 
**[http://ww1.microchip.com/downloads/en/DeviceDoc/Asm30_Link_Util_51317e.pdf MPLAB ASM30, MPLAB LINK30 and Utilities User's Guide]
**[http://ww1.microchip.com/downloads/en/DeviceDoc/51322d.pdf dsPIC30F Language Tools Quick Reference Card]
+
 
 +
===Code Examples===
 +
*[http://www.microchip.com/stellent/idcplg?IdcService=SS_GET_PAGE&nodeId=1408 Microchip Example Codes for dsPic]
 +
 
 +
===Related Development===
 +
*[[Ethernet Module]]
 +
*[[Modulation Plugin]]
  
  
 
==Programming Methods==
 
==Programming Methods==
 
 
*There are 2 programming methods: In-Circuit Serial Programming (ICSP) and Run-Time Self-Programming (RTSP)
 
*There are 2 programming methods: In-Circuit Serial Programming (ICSP) and Run-Time Self-Programming (RTSP)
 
*ICSP allows the devices to be programmed after being placed in a circuit board.
 
*ICSP allows the devices to be programmed after being placed in a circuit board.
 
*RTSP allows the devices to be programmed when an embedded program is already in operation.
 
*RTSP allows the devices to be programmed when an embedded program is already in operation.
  
===ICSP===
+
===ICSP: External Programmer (ICD2)===
*Two types of ICSP are available: '''ICSP''' and '''Enhanced ICSP'''. Both of them require setting ^MCLR to V<sub>IHH</sub> (9V – 13.25V).
+
*Two types of ICSP are available: '''ICSP''' and '''Enhanced ICSP'''. Both of them require setting MCLR# to V<sub>IHH</sub> (9V – 13.25V).
 
*Standard ICSP
 
*Standard ICSP
 
**Use external programmer (e.g. MPLAB<sup>®</sup> ICD 2, MPLAB<sup>®</sup> PM3 or PRO MATE<sup>®</sup> II) only.
 
**Use external programmer (e.g. MPLAB<sup>®</sup> ICD 2, MPLAB<sup>®</sup> PM3 or PRO MATE<sup>®</sup> II) only.
 
**Required low-level programming to erase, program and verify the chip.
 
**Required low-level programming to erase, program and verify the chip.
 
**Slower, because codes are serially executed.
 
**Slower, because codes are serially executed.
**Program memory can be erased using ''Normal-Voltage'' (4.5 – 5.5V) or ''Low-Voltage'' (2.5V – 4.5V).
 
  
 
*Enhanced ICSP
 
*Enhanced ICSP
Line 72: Line 112:
 
**PE contains a small command set to erase, program and verify the chip, avoiding the need of low-level programming.
 
**PE contains a small command set to erase, program and verify the chip, avoiding the need of low-level programming.
  
*Hardware Interface
+
====Hardware Interface====
 
{| border="1" cellspacing="0" cellpadding="5"
 
{| border="1" cellspacing="0" cellpadding="5"
|+ Table 2.1 Pin Used by ICSP
+
|+ Pin Used by ICSP
 
! Pin Label !! Function !! Pin Number
 
! Pin Label !! Function !! Pin Number
 
|-  
 
|-  
| ^MCLR || Programming Enable|| 7
+
| MCLR# || Programming Enable|| 7
 
|-
 
|-
 
| V<sub>DD</sub> || Power Supply || 10, 26, 38, 57
 
| V<sub>DD</sub> || Power Supply || 10, 26, 38, 57
Line 91: Line 131:
  
 
{| border="1" cellspacing="0" cellpadding="5"
 
{| border="1" cellspacing="0" cellpadding="5"
|+ Table 2.2 Available Programmers in the Market
+
|+ Available Programmers in the Market
 
! Product Name
 
! Product Name
 
! Interface with PC
 
! Interface with PC
 
! Interface with Device
 
! Interface with Device
! Price (US)
+
! *Price (US)
! Postage (US)
+
! Remarks
! Total (US)
 
 
|-  
 
|-  
 
| [http://direct.www.microchip.com/stellent/idcplg?IdcService=SS_GET_PAGE&nodeId=1406&dDocName=en010046&part=DV164005 MPLAB<sup>®</sup> ICD 2]
 
| [http://direct.www.microchip.com/stellent/idcplg?IdcService=SS_GET_PAGE&nodeId=1406&dDocName=en010046&part=DV164005 MPLAB<sup>®</sup> ICD 2]
| USB/RS232
+
| USB or RS232
 
| [http://www.microchip.com/Microchip.WWW.SecureSoftwareList/secsoftwaredownload.aspx?device=en010046&lang=en&ReturnURL=http://www.microchip.com/stellent/idcplg?IdcService=SS_GET_PAGE&nodeId=1406&dDocName=en010046&part=DV164005# 6-PIN RJ-12 connector]
 
| [http://www.microchip.com/Microchip.WWW.SecureSoftwareList/secsoftwaredownload.aspx?device=en010046&lang=en&ReturnURL=http://www.microchip.com/stellent/idcplg?IdcService=SS_GET_PAGE&nodeId=1406&dDocName=en010046&part=DV164005# 6-PIN RJ-12 connector]
 
| $159.99
 
| $159.99
 
| -
 
| -
| -
 
|-
 
| [http://www.kanda.com/index.php3?cs=1&bc=direct&bw=%2Fbrowse.php3%3Fnode%3D114%26semisupport%3D PRESTO PIC Programmer Plus]
 
| USB
 
| ?
 
| $200.16
 
| $15.00
 
| $215.16
 
 
|-
 
|-
| [http://www.etekronics.com/product_info.php?cPath=24&products_id=48  Full Speed USB Microchip ICD2<br> Debugger and Programmer]
+
| [http://www.sureelectronics.net Clone Microchip ICD2] (Now Using)
 
| USB
 
| USB
| 6-PIN ICSP connector<br>6-PIN RJ-12 connector
 
| $72.00
 
| $12.00
 
| $84.00
 
|-
 
| [http://www.etekronics.com/product_info.php?cPath=24&products_id=47 Mini Microchip Compatible ICD2<br> Debugger and Programmer]
 
| RS232
 
| 6-PIN ICSP connector<br>6-PIN RJ-12 connector
 
| $45.00
 
| $10.00
 
| $55.00
 
|-
 
| [http://www.inexglobal.com/microcontroller.php ICDX30]
 
| RS232
 
| 6-pin RJ-11
 
| $51.00
 
| $47.46
 
| $98.46
 
|-
 
| [http://www.sure-electronics.net/englishsite/icd2/icd2.htm Clone Microchip ICD2]
 
| RS232
 
 
| 6-pin flat cables
 
| 6-pin flat cables
| $30.00
+
| $52.35
| $12.00
+
| Do not work with new MPLAB versions (works for 7.50), communication to MPLAB may sometime hang (see [http://www.sureelectronics.net/pdfs/DB-DP003.pdf manual])
| $42.00
 
 
|-
 
|-
 
|}
 
|}
 +
<nowiki>*</nowiki>For reference only (exclude shipping), subject to change
  
  
 
{| border="1" cellspacing="0" cellpadding="5"
 
{| border="1" cellspacing="0" cellpadding="5"
|+ Table 2.3 DIY ICD 2 Programmer Circuit
+
|+ DIY ICD 2 Programmer Circuit
 
! Source !! Schematic !! PIC16F877A Bootloader
 
! Source !! Schematic !! PIC16F877A Bootloader
 
|-  
 
|-  
Line 158: Line 168:
 
|}
 
|}
  
*Software Interface
 
**The program can be written and compiled in an Integrated Development Environment (IDE) using either Assembly or C. The complied codes are then loaded to the device through the external programmer.
 
  
 +
====Software Interface====
 +
*The program can be written and compiled in an Integrated Development Environment (IDE) using either Assembly or C. The complied codes are then loaded to the device through the external programmer.
  
 
{| border="1" cellspacing="0" cellpadding="5"
 
{| border="1" cellspacing="0" cellpadding="5"
|+ Table 2.4 Summary of IDE
+
|+ Summary of IDE
 
! Product Name !! Features !! OS !! Price (US$)
 
! Product Name !! Features !! OS !! Price (US$)
 
|-  
 
|-  
Line 176: Line 186:
 
| $895.00 (Free student version<sup>1</sup>)
 
| $895.00 (Free student version<sup>1</sup>)
 
|-
 
|-
| [http://linux.softpedia.com/get/Science-and-Engineering/Electronic-Design-Automation-EDA-/Piklab-8099.shtml Piklab 0.12.0]
+
| [http://piklab.sourceforge.net/ Piklab]
 
| Assembler and C-Compiler
 
| Assembler and C-Compiler
 
| Linux
 
| Linux
| Free<sup>2</sup>
+
| Free
 
|}
 
|}
# Full-featured for the first 60 days. After 60 days only optimization level 1 can be enabled in the compiler. The compiler will continue to function after 60 days, but code size may increase.
+
# Full-featured for the first 60 days. After 60 days, some code optimization functions are disabled. The compiler will continue to function after 60 days, but code size may increase.
# The current version supports external programmer ICD 2, but not yet tested.
 
 
 
===RTSP===
 
*RTSP works in normal voltage (^MCLR no need to raise to V<sub>IHH</sub>).
 
*No literature has mentioned the incorporation of Programming Executive (PE). Presumably, since Enhanced ICSP needs to set ^MCLR to V<sub>IHH</sub>, RTSP cannot use PE.
 
*Refer to bootloader section.
 
  
 
+
===RTSP: COM Port (Bootloader)===
==Circuit Design and PCB==
+
*RTSP works in normal voltage (MCLR# no need to raise to V<sub>IHH</sub>).
 
+
*No literature has mentioned the incorporation of Programming Executive (PE). Presumably, since Enhanced ICSP needs to set MCLR# to V<sub>IHH</sub>, RTSP cannot use PE.
===IC Requirements===
+
*Refer to [[DsPIC30F_5011_Development_Board#Bootloader_Development | bootloader section]].
{|border="1" cellspacing="0" cellpadding="5"
 
|+ Table 3.1 IC Requirements
 
! Part No. !! Description
 
! Min Temp !! Max Temp !! Min Volt !! Max Volt !! Typ Cur !! Max Cur
 
|-valign="top"
 
| [http://ww1.microchip.com/downloads/en/DeviceDoc/70116F.pdf dsPIC30F5011-30I/PT] || uP
 
| -40<sup>o</sup>C || 85<sup>o</sup>C
 
| 2.5V <sup>[1]</sup>|| 5.5V
 
|    || 250mA
 
|-
 
| [http://datasheets.maxim-ic.com/en/ds/MAX3222-MAX3241.pdf MAX3232ESE] || RS232 driver
 
| -40<sup>o</sup>C || 85<sup>o</sup>C
 
| 3.0V || 5.5V
 
| 0.3mA || 1.0mA
 
|-
 
| [http://www.analog.com/UploadedFiles/Data_Sheets/ADM483E.pdf ADM483E ANZ] || RS485 driver
 
| -40<sup>o</sup>C || 85<sup>o</sup>C
 
| 4.5V || 5.5V
 
| 0.036mA ||
 
|-
 
| [http://focus.ti.com/lit/ds/symlink/dac6574.pdf DAC6574DGS] || 10-bit Quad-DAC I<sup>2</sup>C
 
| -40<sup>o</sup>C || 105<sup>o</sup>C
 
| 2.7V || 5.5V
 
| 0.6mA || 0.9mA
 
|-
 
| [http://www.semiconductors.philips.com/acrobat/datasheets/74HC_HCT14_3.pdf 74HC14D] || Quad-Schmitt Trigger
 
| -40<sup>o</sup>C || 125<sup>o</sup>C
 
| 2.0V || 6.0V
 
| || 50mA
 
|-
 
| Overall ||
 
| -40<sup>o</sup>C || 85<sup>o</sup>C
 
| 4.5V || 5.5V
 
| || <310mA <sup>[2]</sup>
 
|-
 
|}
 
#Minimum voltage measured is 3.3V (with 2 LEDs blinking) running at 30MHz.
 
#Measured current at 5V is 180mA (with 2 LEDs blinking only)
 
 
 
===Module Board===
 
*Functions
 
**Primary communication with other module boards via RS232 over short distance.
 
**Secondary communication with benchtop via RS458 over longer distance.
 
**Digital control I/O for 1 laser (e.g. on/off, detect temp overheat, current alarm)
 
**Analog input for data acquisation on power, current and temperature
 
**Analog output for power and current control
 
 
 
{|border="1" cellspacing="0" cellpadding="5"
 
|+ Table 3.2 Module
 
! Digital Input !! Digital Output !! Analog Input !! Analog Output
 
|-valign="top"
 
| 1. ICSP
 
| 1. LED<br> 2. Bi-color LED<br> 3. RS232<br> 4. RS458<br> 5. Case temp overheat<br> 6. Laser on/off 1,2<br> 7. Interlock<br> 8. Digital ctrl<br> 9. Current 0,1 alarm<br>
 
| 1. Case temp<br> 2. pow 0,1<br> 3. cur0<br> 4. temp0
 
| 1. 10-bit DAC
 
|-
 
|}
 
 
 
===Benchtop===
 
*Functions
 
**Primary communciation with module boards via RS485
 
**Secondary communication with other benchtops via RS232
 
**Digital I/O control for 2 lasers
 
**Analog inputs on power, current and temperature
 
**Analog outputs for power and current control
 
**LCD display and rotary key for user input
 
 
 
{|border="1" cellspacing="0" cellpadding="5"
 
|+ Table 3.3 Base Benchtop
 
! Digital Input !! Digital Output !! Analog Input !! Analog Output
 
|-valign="top"
 
| 1. ICSP<br> 2. Rotary Key<br> 3. Push Buttons
 
| 1. LED<br> 2. RS232<br> 3. RS458<br> 4.LCD display<br> 5. Buzzer<br> 6. Digital Ctrl 0,1
 
| 1. Case temp<br> 2. CurrentDetect 0,1<br> 3. PowerDetect 0,1,2,3<br> 4. TempDetect
 
| 1. 10-bit DAC (PowerCurrentCtrl 0,1)
 
|-
 
|}
 
  
  
Line 281: Line 208:
 
**MPLAB C30 C Compiler (*.c -> *.s)
 
**MPLAB C30 C Compiler (*.c -> *.s)
 
**MPLAB ASM30 Assembler (*.s -> *.o)
 
**MPLAB ASM30 Assembler (*.s -> *.o)
**MPLAB LINK30 Linker (*.o -> *.exe)
+
**MPLAB LINK30 Linker (*.o -> *.bin)
  
 
*PA optimizer, simulator, runtime libraries, header files, include files, and linker scripts are not covered by GNU. Reference is [http://direct.forum.microchip.com/tm.aspx?m=107208 here].
 
*PA optimizer, simulator, runtime libraries, header files, include files, and linker scripts are not covered by GNU. Reference is [http://direct.forum.microchip.com/tm.aspx?m=107208 here].
  
 
*Microchip has integrated ASM30, LINK30, assembly header files, linker scripts in MPLAB IDE, which is free for download.
 
*Microchip has integrated ASM30, LINK30, assembly header files, linker scripts in MPLAB IDE, which is free for download.
*MPLAB C30 costs US$895. A 60-day free student version is also available. After 60-days, the optimizer is automatically disabled, while other tools can still function properly. Refer to Table 2.4.
+
*MPLAB C30 costs US$895. A 60-day free student version is also available. After 60-days, the optimizer is automatically disabled, while other tools can still function properly.
  
 
*C-libraries contained in C30 includes (Refer to [http://ww1.microchip.com/downloads/en/DeviceDoc/16bit_Language_Tool_Libraries_51456c.pdf 16-Bit Language Tools Libraries] from Microchip).
 
*C-libraries contained in C30 includes (Refer to [http://ww1.microchip.com/downloads/en/DeviceDoc/16bit_Language_Tool_Libraries_51456c.pdf 16-Bit Language Tools Libraries] from Microchip).
Line 292: Line 219:
  
 
{|border="1" cellspacing="0" cellpadding="5"
 
{|border="1" cellspacing="0" cellpadding="5"
|+ Table 4.1 C Libraries in MPLAB C30
+
|+ C Libraries in MPLAB C30
 
! Library !! Directory <br>(\\Microchip\MPLAB C30) !! Major functions
 
! Library !! Directory <br>(\\Microchip\MPLAB C30) !! Major functions
 
|-valign="top"
 
|-valign="top"
Line 299: Line 226:
 
| Vector, Matrix, Filter, etc.
 
| Vector, Matrix, Filter, etc.
 
|-valign="top"
 
|-valign="top"
| 16-Bit Peripheral Libraries <br>(e.g. libp30F5011-coff.a)
+
| 16-Bit Peripheral Libraries
 
| \lib <br> \src\peripheral <br> \support\h
 
| \lib <br> \src\peripheral <br> \support\h
 
| ADC12, IOPort, UART, I<sup>2</sup>C, etc.
 
| ADC12, IOPort, UART, I<sup>2</sup>C, etc.
Line 321: Line 248:
 
**Current MPLAB ASM30 Assembler: v2.04
 
**Current MPLAB ASM30 Assembler: v2.04
 
**Current MPLAB C30 Compiler: v2.04
 
**Current MPLAB C30 Compiler: v2.04
 +
*'''Important Note''': Only the compiler is free. The header files and library are owned by Microchip.
  
*[http://gcc.gnu.org/ml/gcc/2005-02/msg01144.html John Steele Scott] has made templates that can be readily used by Debian-based systems. Someone at http://noel.feld.cvut.cz/dspic/ has done the necessary conversion to *.deb already.
+
{|border="1" cellspacing="0" cellpadding="5"
**Download '''pic30-1.32-debian.tar.bz2''' for Template v1.32. (For v2.01, please goto [http://thread.gmane.org/gmane.comp.hardware.microcontrollers.gnupic/3768/focus=3768  pic30-debian-2.01.tar.bz2]).
+
|+ Pic30 C-Compiler Toolchain Templates for Conversion to Debian-based systems
**Download '''pic30-binutils_1.32-1_i386.deb''' for the assember.
+
! Toolchain Source !! Instruction !! Remarks
**Download '''pic30-gcc_1.32-1_i386.deb''' for the compiler.
+
|-valign="top"
 +
| [http://www.baycom.org/~tom/dspic/ v2.00]
 +
| Download pic30-gcc-2.00-1.i386.rpm and pic30-binutils-2.00-1.i386.rpm.<br>Convert to deb files.
 +
| Stable<br>Now using
 +
|-valign="top"
 +
| [http://www.nabble.com/Debian-templates-for-dsPIC-build-toolchain-2.05-td7886279.html v2.05]
 +
| Reference to example below, but use 2.05 files
 +
| Can compile<br>Stable but not heavily tested
 +
|-valign="top"
 +
| [http://www.nabble.com/Debian-templates-for-dsPIC-build-toolchain-3.01-tf4308624.html v3.01]
 +
| Follow example below
 +
| Can compile<br>Unstable (sometime produce segmentation fault)
 +
|-valign="top"
 +
| [http://www.nabble.com/Debian-Template-Patches-for-C30-v3.10-i386-td17534084.html v3.10]
 +
| Reference to example below, but use 3.10 files
 +
| Cannot compile yet (segmentation fault)
 +
|-
 +
|}
 +
====Conversion Example====
 +
*Pre-install these packages: dpkg-dev, debhelper, bison, flex, sysutils, gcc-3.3, fakeroot
 +
**cmd: '''sudo apt-get install dpkg-dev debhelper bison flex sysutils gcc-3.3 fakeroot'''
 +
*Download and unzip template: '''pic30-3.01.tar.bz2'''
 +
*Download assembler: '''mplabalc30v3_01_A.tar.gz'''. Save under /pic30-3.01/pic30-binutils-3.01/upstream/
 +
*Download c-compiler: '''mplabc30v3_01_A.tgz'''. Save under /pic30-3.01/pic30-gcc-3.01/upstream/
 +
*Install MPLAB_C30_v3_01-StudentEdition under Windows
 +
*Copy directories /include, /lib, /support, and /bin/c30_device.info to pic30-3.01/pic30-support-3.01/upstream/
 +
*Pack pic30-binutils into deb file
 +
**goto /pic30-3.01/pic30-binutils-3.01/
 +
**type cmd: '''dpkg-buildpackage -rfakeroot -b'''
 +
*Install pic30-binutils_3.01-1_i386.deb
 +
**type cmd: '''sudo dpkg -i pic30-binutils_3.01-1_i386.deb'''
 +
*Pack pic30-gcc-3.01 into deb file
 +
**goto /pic30-3.01/pic30-gcc-3.01/
 +
**type cmd: '''dpkg-buildpackage -rfakeroot -b'''
 +
*Install pic30-gcc_3.01-1_i386.deb
 +
**type cmd: '''sudo dpkg -i pic30-gcc_3.01-1_i386.deb'''
 +
*Pack support files into deb file
 +
**goto /pic30-3.01/pic30-support-3.01/
 +
**type cmd: '''dpkg-buildpackage -rfakeroot -b'''
 +
*Install pic30-support_3.01-1_all.deb
 +
**type cmd: '''sudo dpkg -i pic30-support_3.01-1_all.deb'''
 +
*After installation, locations of
 +
**C-Header (*.h): /usr/pic30-elf/include
 +
**Libraries (*.a): /usr/pic30-elf/lib
 +
**Assembly header (*.inc): /usr/share/pic30-support/inc
 +
**Linkerscript (*.gld): /usr/share/pic30-support/gld
  
*'''Important Note''': Only the compiler is free. The header files and library is owned by Microchip.
+
===Burning Program Codes to Target Board===
**Thomas Sailer suggested to download the Student version of C30 compiler and then build the libraries without source code. A package template for Fedora system is available [http://www.baycom.org/~tom/dspic/ here].
 
**Instructions for filling the upstream direction is available [http://forum.microchip.com/printable.aspx?m=139360 here].
 
**Alteratively, [https://gna.org/projects/pic30-libc/ Stephan Walter] has started a project to develop C Runtime Library for dsPIC.
 
***Current libraries in version 0.1.1 include: assert.h, cdefs.h, ctype.h, errno.h, inttypes.h, stdint.h, stdio.h, stdlib.h, string.h
 
 
 
*Burning Program Codes to Target Board
 
 
#Use 'dspicprg and dspicdmp' utilities developed by [http://homerreid.ath.cx/misc/dspicprg/ Homer Reid] to burn hex code (*.hex) to devices. See Reference [http://forum.microchip.com/tm.aspx?m=94243 here]. Through serial port only?
 
#Use 'dspicprg and dspicdmp' utilities developed by [http://homerreid.ath.cx/misc/dspicprg/ Homer Reid] to burn hex code (*.hex) to devices. See Reference [http://forum.microchip.com/tm.aspx?m=94243 here]. Through serial port only?
 
#Use [http://piklab.sourceforge.net/ Piklab IDE]. Details on file format not known.
 
#Use [http://piklab.sourceforge.net/ Piklab IDE]. Details on file format not known.
Line 339: Line 306:
  
 
===Code Optimization===
 
===Code Optimization===
*Code Optimization under GNU license supports O0 and O1 only.
+
*Below is a comparsion between different optimization levels for the project including drivers for 2 projects.
*MPLAB C-Compiler supports O0, O1, O2, Os and O3. The Student version will disable O2, Os, and O3 after 60 days.
 
*Below is a comparsion between different optimization levels for the project including drivers for uart, i2c, adc and eeprom.
 
 
 
  
 
{|border="1" cellspacing="0" cellpadding="5"
 
{|border="1" cellspacing="0" cellpadding="5"
|+ Table 4.2 Comparison between differnt optimization levels
+
|+ Comparison between differnt optimization levels
! Optimization !! Description !! Code Size (byte) !! Data Usage (byte)
+
! Optimization !! Description !! Project 1<br>Code Size<br>(byte) !! Project 1<br>Data Usage<br>(byte) !! Project 2<br>Code Size<br>(byte) !! Project 2<br>Data Usage<br>(byte)
 
|-valign="top"
 
|-valign="top"
 
| O0  
 
| O0  
 
| No optimization<br>Fastest Compilation
 
| No optimization<br>Fastest Compilation
| 6222 (9%) || 178 (4%)
+
| 6222 (9%) || 178 (4%) || 26,037 (38%) || 710 (17%)
 
|-valign="top"
 
|-valign="top"
 
| O1  
 
| O1  
 
| Optimize<br> Tries to reduce code size and execution time.
 
| Optimize<br> Tries to reduce code size and execution time.
| 4473 (6%) || 178 (4%)
+
| 4473 (6%) || 178 (4%) || 22,290 (32%) || 710 (17%)
 
|-valign="top"
 
|-valign="top"
 
| O2  
 
| O2  
 
| Optimize even more<br> Performs nearly all supported optimizations <br>that do not involve a space-speed trade-off. <br>Increases both compilation time and the <br>performance of the generated code.
 
| Optimize even more<br> Performs nearly all supported optimizations <br>that do not involve a space-speed trade-off. <br>Increases both compilation time and the <br>performance of the generated code.
| 4422 (6%) || 178 (4%)
+
| 4422 (6%) || 178 (4%) || 21,993 (32%) || 710 (17%)
 
|-valign="top"
 
|-valign="top"
 
| O3  
 
| O3  
 
| Optimize yet more. <br>O3 turns on all optimizations specified by O2 <br>and also turns on the inline-functions option.
 
| Optimize yet more. <br>O3 turns on all optimizations specified by O2 <br>and also turns on the inline-functions option.
| 4356 (6%) || 178 (4%)
+
| 4485 (6%) || 178 (4%) || 22,176 (32%) || 710 (17%)
 
|-valign="top"
 
|-valign="top"
 
| Os  
 
| Os  
 
| Optimize for size. <br>Os enables all O2 optimizations that do not <br>typically increase code size. It also performs <br>further optimizations designed to reduce code <br>size.
 
| Optimize for size. <br>Os enables all O2 optimizations that do not <br>typically increase code size. It also performs <br>further optimizations designed to reduce code <br>size.
| 4485 (6%) || 178 (4%)
+
| 4356 (6%) || 178 (4%) || 21,885 (32%) || 710 (17%)
 
|-
 
|-
 
|}
 
|}
  
  
==Software Architecture==
+
==[[freertos_posix Development | Driver Development]]==
*Architecture
+
*Description on developing drivers with POSIX API
  +----------+-----------+---------+---------+
 
  |  local  |  remote  |        |        |
 
  +----------+-----------+  host  |  UI    |
 
  |      data access    | channel |        |
 
  |    (DI,DO,AI,AO)    |        |        |
 
  +----------------------+---------+---------+
 
  |              Application                |
 
  |                                          |
 
  +------------------------------------------+
 
  |            Applications Model            |
 
  |      +--------------+-----------+      |
 
  |      |    GUI      |  CLib    |      |
 
  |      |      +------+-----------+-------+
 
  |      |      |    Operating System    |
 
  +-------+-------+--------------------------+
 
  |                Drivers                  | 
 
  +------------------------------------------+
 
  |              Hardware                  | 
 
  +------------------------------------------+
 
*Currently, operating system is based on [http://www.psocdeveloper.com/forums/viewtopic.php?p=973&sid=717d6b7e86472a5036f7cfbbcb0c05aa linlike8]. The possibility of using other OS (e.g. [http://www.freertos.org/ FreeRTOS]) will be explored later.
 
*Software Drivers are to be developed to allow users at Application Level to use the hardware (e.g. ADC, DAC, UART, EEPROM) through the OS.
 
*The interface between the drivers and the OS should be compliant with [http://www.die.net/doc/linux/man/man2/ PoSIX standard] for Linux (e.g. open(), write(), read(), ioctl() etc).
 
 
 
 
 
==Programming Tips==
 
 
 
===Memory Map for 5011===
 
        16-bit
 
<-------------------->
 
+--------------------+ 0x000000<br>
 
|       Flash        | <br>
 
|  (22K x 16 bits)  | <br>           
 
+--------------------+ 0x00B000<br>
 
|      Reserved      | <br>
 
+--------------------+ 0x7FFC00<br>
 
|      EEPROM        | <br>
 
|  (1K x 8 bits)    | <br>
 
+--------------------+ 0x800000<br>
 
|    Programming    | <br>
 
|    Executive      | <br>
 
+--------------------+ 0x8005C0<br>
 
|      Unit ID      | <br>
 
+--------------------+ 0x800600<br>
 
|      Reserved      | <br>
 
+--------------------+ 0xF80000<br>
 
| Config  Registers  | <br>
 
+--------------------+ 0xF80010<br>
 
|      Reserved      | <br>
 
+--------------------+ 0xFF0000<br>
 
| Device ID (0x0080) | <br>
 
+--------------------+ 0xFF0004<br>
 
|      Reserved      | <br>
 
+--------------------+ 0xFFFFFE<br>
 
 
 
===Data Location===
 
{| border="1" cellspacing="0" cellpadding="5"
 
|+ Table 6.1 Data Location
 
! Type !! Description !! Example
 
|-valign="top"
 
| _XBSS(N) <sup>[1]</sup>
 
| RAM Data in X-memory, aligned at N, no initilization
 
| int _XBSS(32) xbuf[16];
 
|-valign="top"
 
| _XDATA(N) <sup>[1]</sup>
 
| RAM Data in X-memory, aligned at N, with initilization
 
| int _XDATA(32) xbuf[] = {1, 2, 3, 4, 5};
 
|-valign="top"
 
| _YBSS(N) <sup>[1]</sup>
 
| RAM Data in Y-memory, aligned at N, no initilization
 
| int _YBSS(32) ybuf[16];
 
|-valign="top"
 
| _YDATA(N) <sup>[1]</sup>
 
| RAM Data in Y-memory, aligned at N, with initilization
 
| int _YDATA(32) ybuf[16] = {1, 2, 3, 4, 5};
 
|-valign="top"
 
| __attribute__((space(const)))
 
| Flash ROM data, constant, accessed by normal C statements, but 32K max.
 
| int i __attribute__((space(const))) = 10;
 
|-valign="top"
 
| __attribute__((space(prog)))
 
| Flash ROM data, read/write by program space visibility window (psv)
 
| int i __attribute__((space(prog)));
 
|-valign="top"
 
| __attribute__((space(auto_psv)))
 
| Flash ROM data, read by normal C statements, write by accessing psv
 
| int i __attribute__((space(auto_psv)));
 
|-valign="top"
 
| __attribute__((space(psv)))
 
| Flash ROM data, read/write by (psv)
 
| int i __attribute__((space(psv)));
 
|-valign="top"
 
| _EEDATA(N) <sup>[1]</sup>
 
| ROM Data in EEPROM, aligned at N, read/write with psv
 
| int _EEDATA(2) table[]={0, 1, 2, 3, 5, 8};
 
|-valign="top"
 
| _PERSISTENT
 
| RAM Data, data remain after reset
 
| int _PERSISTENT var1, var2;
 
|-valign="top"
 
| _NEAR
 
| RAM Data at near section
 
| int _NEAR var1, var2;
 
|-valign="top"
 
| _ISR
 
| Interrupt service rountine
 
| void _ISR _INT0Interrupt(void);
 
|-valign="top"
 
| _ISRFAST
 
| Fast interrupt service rountine
 
| void _ISRFAST _T0Interrupt(void);
 
|-
 
|}
 
#N must be a power of two, with a minimum value of 2.
 
 
 
----
 
 
 
===Configuration Bits===
 
*System clock source can be provided by:
 
#Primary oscillator (OSC1, OSC2)
 
#Secondary oscillator (SOSCO and SOSCI) with 32kHz crystal
 
#Internal Fast RC (FRC) oscillator at 7.37MHz
 
#Low-Power RC (LPRC) oscillator (Watchdog Timer) at 512 kHz.
 
*These clock sources can be incorporated with interal Phase-locked-loop (PLL) x4, x8 or x16 to yield the osciallator frequrence F<sub>OSC</sub>
 
*The system clock is divided by 4 to yield the internal instruction cycle clock, F<sub>CY</sub>=F<sub>OSC</sub>/4
 
*FRC with PLLx16 is used to achieve F<sub>CY</sub>=29.48MHz (30MIPS)
 
 
 
  //The code (MACRO) below is to be placed at the top of program (before main)
 
    _FOSC(CSW_FSCM_OFF & FRC_PLL16);
 
    _FWDT(WDT_OFF);    //Turn off Watchdog Timer
 
    _FBORPOR(PBOR_ON & BORV_27 & MCLR_DIS & PWRT_16);
 
    _FGS(CODE_PROT_OFF); //Disable Code Protection
 
 
 
----
 
===Timer===
 
*Each timer is 16-bit (i.e. counting from 0 to 65535).
 
*Timer 2 and 3 can be incorporated together to form a 32-bit timer.
 
*Prescale is the ratio between timer counts and system clock counts. Prescales of 1:1, 1:8, 1:64 and 1:256 are available.
 
*Timers may be used to implement free time clock or mesaure time.
 
 
 
====Free Time Clock====
 
*Let required time for ticking be PERIOD.
 
*Number of instruction cycles during PERIOD = PERIOD*F<sub>CY</sub> cycles
 
*Using a prescale of 1:x, the timer period count register = # of cycles/x
 
*e.g. PERIOD = 10ms; # of cycles = 10ms*30MHz = 300000 cylces; Using 1:64 Prescale, register setting = 300000/64 = 4688
 
  void time_init(void){
 
      TMR1 = 0; // Clear register
 
      PR1 = 4688; // Set period
 
      //============================================================
 
      _T1IF = 0; // Clear interrupt flag
 
      _T1IE = 1; // Enable interrupts
 
      //============================================================
 
      T1CONbits.TCS = 0; // Use internal clock source
 
      T1CONbits.TCKPS = 2; // Prescale Select 1:64
 
      T1CONbits.TON = 1; // Start the timer
 
  }
 
  //********************************************************************
 
  void _ISRFAST _T1Interrupt(void){
 
      _T1IF = 0; // Clear interrupt flag
 
      //Place user code here
 
  }
 
 
 
====Time Measurement====
 
*To measure the time taken for action(), use the code below:
 
  unsigned int measure_time(void){
 
      PR3 = 0xFFFF; // Set counter to maximum
 
      _T3IF = 0; // Clear interrupt flag
 
      _T3IE = 0; // Disable interrupt
 
      T3CONbits.TON = 1; // Start the timer, TMR3 count up
 
      TMR3 = 0; //Clear TMR3 to start count up
 
      //====================================================
 
      //Add code here to wait for something to happen
 
      action();
 
      //====================================================
 
      T3CONbits.TON = 0; //Stop the timer
 
      //====================================================
 
      unsigned int time = TMR3/FCY;      //TMR/FCY yields the actual time
 
  }
 
 
 
----
 
 
 
===Interrupt===
 
*Registers are involved in Interrupts includes:
 
#Interrupt Flag Status (IFS0-IFS2) registers
 
#Interrupt Enable Control (IEC0-IEC2) registers
 
#Interrupt Priority Control (IPC0-IPC10) registers
 
#Interrupt Priority Level (IPL) register
 
#Global Interrupt Control (INTCON1, INTCON2) registers
 
#Interrupt vector (INTTREG) register
 
*User may assign priority level 0-7 to a specific interrupt using IPC. Setting priority to 0 disable a specific interrupt. Level 7 interrupt has the highest priority.
 
*Current priority level is stored in IPL. Setting IPL to 7 disables all interrupts (except traps). The following MACROs are defined in <p30f5011.h>:
 
#SET_CPU_IPL(ipl): Set IPL to ipl
 
#SET_AND_SAVE_CPU_IPL(save_to, ipl): Store the current IPL to save_to and then set to ipl
 
#RESTORE_CPU_IPL(saved_to): Restore the previously saved ipl
 
*sti() and cli() are defined to enable and disable global interrupts for time critical functions:
 
  extern int SAVE_IPL;
 
  #define sti() RESTORE_CPU_IPL(SAVE_IPL)
 
  #define cli() SET_AND_SAVE_CPU_IPL(SAVE_IPL, 7)
 
  //============================================================
 
  char adc_ioctl(unsigned char request, unsigned char* argp){
 
    //...
 
    cli(); //Disable global interrupt
 
    for(;ch<=argp[0];ch++)
 
      adc_add_ch(argp[ch]); //Add adc channels
 
    sti(); //Enable global interrupt
 
    //...
 
    return 0;
 
  }
 
 
 
----
 
 
 
===UART===
 
*5011 provides two UART channels UxART, for x=1, 2.
 
*UxMODE, UxSTA, UxBRG are registers used to set the mode, indicate the status, and set the baud rate respectively.
 
*For UART communications compatiable with RS232 standard, an external driver (e.g. MAX3232ESE) is needed.
 
*For UART communications compatiable with RS485 standard, an external driver (e.g. DS3695N) is needed.
 
====Auto baud rate detection====
 
*The method is provided by [http://www.opencircuits.com/DsPIC30F_5011_Development_Board ingenia bootloader].
 
*The PC sends a ASCII character 'U' (0x55) to the target board.
 
*On the first rising edge of the start bit, the target board starts the timer.
 
*At the fifth rising edge, the timer is stopped, let the count number be ''t_count''.
 
**The measured period corresponds to 8 bits transmitted at a baud rate ''uxbrg''.
 
    _  _  _  _  _  _
 
  _|S|_|1|_|1|_|1|_|1|_|S|_  (S = Start Bit)
 
    <--------------->
 
    Measured Time
 
*The relationship between ''uxbrg'' and ''TMR'' is
 
  Measured Time (in seconds) = t_count/F<sub>cy</sub>
 
  uxbrg = 1/(Measured Time/8)
 
        = 8*F<sub>cy</sub>/t_count
 
*Since UxBRG is computed by:
 
  UxBRG = (F<sub>cy</sub>/(16*Baudrate)) -1
 
        = (F<sub>cy</sub>/(16*8*F<sub>cy</sub>/t_count)) -1
 
        = t_count/128 -1
 
*The following is the code for auto baud rate detection for U2ART:
 
  unsigned int uart2_autobaud(void){
 
      U2MODEbits.ABAUD = 1; //Enable Autobaud detect from U2RX (from IC2 if 0)
 
      U2MODEbits.UARTEN = 1; //U2ART enable
 
      //Timer 3 Config==========================================================
 
      PR3 = 0xFFFF; // Set counter to maximum
 
      _T3IF = 0; // Clear interrupt flag
 
      _T3IE = 0; // Disable interrupt
 
      T3CONbits.TON = 1; // Start the timer, TMR3 count up
 
      //Input Capture Config====================================================
 
      IC2CONbits.ICM = 3; //Detect rising
 
      _IC2IF = 0; //Clear interrupt flag
 
      _IC2IE = 0; //Disable interrupt
 
      //Start Auto baud detection===============================================
 
      unsigned int i=0;
 
      cli(); //Disable Global Interrupt
 
      while(!_IC2IF); //1st rising edge detected
 
      TMR3 = 0; //Clear TMR3 to start count up
 
      _IC2IF = 0; //Clear interrupt flag
 
      while(!_IC2IF); //2nd rising edge detected
 
      _IC2IF = 0; //Clear interrupt flag
 
      while(!_IC2IF); //3rd rising edge detected
 
      _IC2IF = 0; //Clear interrupt flag
 
      while(!_IC2IF); //4th rising edge detected
 
      _IC2IF = 0; //Clear interrupt flag
 
      while(!_IC2IF); //5th rising edge detected
 
      _IC2IF = 0; //Clear interrupt flag
 
      T3CONbits.TON = 0; //Stop the timer
 
      sti(); //Enable Global Interrupt
 
      //Compute value for BRG register==========================================
 
      unsigned int time;
 
      time = ((TMR3+0x40)>>7)-1; //+0x40 for rounding
 
      //========================================================================
 
      return time;
 
  }
 
*For 30MIP, tested speeds of transmission include 9600bps, 19200bps, 28800bps, 38400bps and 57600bps.
 
====Initialize UART====
 
  void uart2_init(void){
 
      //=================================================================
 
      // Configure Baud rate
 
      //  +-- Default Baud rate = 19.2 kbps
 
      // +-- U2BRG = 29.4912e6 / (16 * 19200) - 1 = 95
 
      unsigned int u2brg = 95;
 
      #if(AUTO_BAUD_DECT>0)
 
      u2brg = uart2_autobaud();
 
      #endif
 
      U2BRG  = u2brg;
 
      //=================================================================
 
      // Disable U2ART
 
      U2MODEbits.UARTEN = 0; //Disable U2ART module
 
      //=================================================================
 
      // Configure Interrupt Priority
 
      _U2RXIF = 0; //Clear Rx interrupt flags
 
      _U2TXIF = 0; //Clear Tx interrupt flags
 
      _U2RXIE = 1; //Receive interrupt: 0 disable, 1 enable
 
      _U2TXIE = 1; //Transmit interrupt: 0 disable, 1 enable
 
      //=================================================================
 
      // Configure Mode
 
      //  +--Default: 8N1, no loopback, no wake in sleep mode, continue in idle mode
 
      //  +--Diable autobaud detect
 
      //  +--Enable U2ART module
 
      U2MODEbits.ABAUD = 0; //Disable Autobaud detect from U2RX
 
      U2MODEbits.UARTEN = 1; //U2ART enable
 
      //=================================================================
 
      // Configure Status
 
      //  +--Default: TxInt when a char is transmitted, no break char
 
      //  +--Default: RxInt when a char is received, no address detect, clear overflow
 
      //  +--Enable Transmit
 
      U2STAbits.UTXEN = 1; //Tx enable
 
  }
 
====Sending and Receiving Data====
 
  void _ISR _U2TXInterrupt(void){
 
      _U2TXIF = 0; //Clear Interrupt Flag
 
      if(tx_data_ready())
 
        U2TXREG = tx_buf[POS]; //send next byte...
 
  }
 
  void _ISR _U2RXInterrupt(void){
 
      _U2RXIF = 0; //Clear the flag
 
      if ( U2STAbits.URXDA ){
 
        rx_buf[POS] = (unsigned char) U2RXREG; //Read the data from buffer
 
      }
 
  }
 
----
 
 
 
===I<sup>2</sup>C===
 
*Two lines are devoted for the serial communication. SCL for clock, SDA for data.
 
*Standard communication speed includes
 
#Standard speed mode: 100kHz
 
#Fast speed mode: 400kHz
 
#High speed mode: 3.4MHz
 
*dsPIC30f5011 supports standard and fast speed modes. The maximum speed attainable is 1MHz.
 
*Pull-up resistors are required for both SCL and SDA. Minimum pull-up resistance is given by:
 
    Pull-up resistor (min) = (V<sub>dd</sub>-0.4)/0.003  ......  [See section 21.8 in Family reference manual]
 
*2.2Kohm is typical for standard speed mode.
 
*After initiating a start/stop/restart bit, add a small delay (e.g. no operation) before polling the corresponding control bit (hardware controlled). For example:
 
      StartI2C();<br>
 
      Nop(); //A small delay for hardware to respond<br>
 
      while(I2CCONbits.SEN); //Wait till Start sequence is completed
 
*After sending a byte and receiving an acknowledgement from the slave device, ensure to change to idle state. For example:
 
      MasterWriteI2C(0x55);<br>
 
      while(I2CSTATbits.TBF); //Wait for transmit buffer to empty<br>
 
      while(I2CSTATbits.ACKSTAT); //Wait for slave acknowledgement<br>
 
      IdleI2C();
 
 
 
----
 
 
 
===ADC===
 
*12-bit ADC: (Max 16 Channels)
 
*Allow a maximum of 2 sets of analog input multiplexer configurations, MUX A and MUX B (Normally use one only).
 
*A maximum of 200kps of sampling rate when using auto sampling mode.
 
====Configuration====
 
*Interrupt: Clear ADC interrupt flag and enable ADC interrupt. The ADC module will be set to interrupt when the specified channels are updated.
 
  _ADIF = 0; //clear ADC interrupt flag
 
  _ADIE = 1; //enable adc interrupt
 
*I/O: Set the corresponding TRISBX bits (digit i/o config) to input (i.e. = 1), and set corresponding bits in ADPCFG (analog config) to zero.
 
  _TRISB2 = 1; //Set AN2 [Case Temp] as analog input
 
  _TRISB8 = 1; //Set AN8 [Power detect 0] as analog input
 
  _TRISB9 = 1; //Set AN9 [Power detect 1] as analog input
 
  _TRISB10 = 1; //Set AN10 [Current detect 0] as analog input
 
  _TRISB11 = 1; //Set AN11 [Temp detect 0] as analog input
 
  ADPCFG = 0xF0FB; //0 => Analog, 1 => Digital
 
*Scanning Mode: Scan mode is used. In this mode, the Sample and Hold (S/H) is switched between the channels specified by ADCSSL (Scan select register).
 
  ADCSSL = 0x0F04; //0 => Skip, 1 => Scan
 
*Reference Voltage for S/H: Only MUX A is used. By default, the negative reference voltage of the S/H is connected to V<sub>REF-</sub>.
 
  ADCHSbits.CH0NA = 0;
 
*Sampling Rate: T<sub>AD</sub> refers to the time unit for the ADC clock. To configure the ADC module at 200kbps, the minimum sampling time of 1T<sub>AD</sub> = 334ns is required. ADCS<5:0> in ADCON3 register is used to set the time, which is given by:
 
      ADCS<5:0> = 2(T<sub>AD</sub>/T<sub>CY</sub>)-1
 
                = 2(334e-9/33.34e-9)-1
 
                = 19
 
 
 
      ADCON3bits.SAMC = 1; //1TAD for sampling time
 
      ADCON3bits.ADRC = 1; //Use internal ADC clock
 
      ADCON3bits.ADCS = 19; //Set TAD = 334ns
 
*Settings for ADC Operation: For 200kbps operation, the voltage references for the ADC voltage are connected to V<sub>REF+</sub> and V<sub>REF-</sub>. Scan input is enabled, and the module will generate an interrupt when all selected channels have been scanned.
 
      ADCON2bits.VCFG = 3; //External Vref+, Vref-
 
      ADCON2bits.CSCNA = 1; //Scan input
 
      ADCON2bits.SMPI = 4; //take 5 samples (one sample per channel) per interrupt
 
*More Settings for ADC Operation: Turn on the module, select the data output format as unsigned integer, and allow auto setting of SAMP bit (auto sampling).
 
      ADCON1bits.ADON = 1; //Turn on module
 
      ADCON1bits.FORM = 0; //[2 fractional]; [3 siged fractional]
 
      ADCON1bits.SSRC = 7; //auto covert, using internal clock source
 
      ADCON1bits.ASAM = 1; //auto setting of SAMP bit
 
====Storing ADC Data====
 
*16 registers (ADCBUF0 -ADCBUF15) are dedicated to store the ADC data between interrupts. However, the data in ADCBUFx does not necessarily correspond to the data taken for channel x. Since the lowest register will always be filled first, when some of the channels are not scanned (i.e. skipped), care must be taken. The following code checks the ADCSSL register for the current scanning channels and moves the data to the corresponding position in *adc_buf.
 
      void _ISR _ADCInterrupt(void){
 
          _ADIF = 0; //Clear adc interrupt
 
          //==========================================================
 
          unsigned char channel = 0;
 
          unsigned char buffer = 0;
 
          for (; channel<ADC_MAX_CH; channel++){
 
              if(adc_ch_updated(channel)){ //Check if channel has updated
 
                    adc_buf[channel] = ADC16Ptr[buffer]; //Copy data to adc_buf
 
                    buffer++;
 
              }
 
          }
 
      }
 
      unsigned char adc_ch_updated(unsigned char ch){
 
          unsigned int mask;
 
          mask = 0x0001 << ch;
 
          if(ADCSSL & mask)
 
              return 1;
 
        return 0;
 
      }
 
====Adding and Removing Channels====
 
*Channels may be added or removed by changing _TRISBX, ADPCFG, ADCSSL and ADCON2bits.SMPI.
 
  void adc_add_ch(unsigned char ch){
 
      //Enable i/o pin as input===========================================
 
      switch(ch){
 
        case 0: _TRISB0 = 1; break;
 
        case 1: _TRISB1 = 1; break;
 
        case 2: _TRISB2 = 1; break;
 
        case 3: _TRISB3 = 1; break;
 
        case 4: _TRISB4 = 1; break;
 
        case 5: _TRISB5 = 1; break;
 
        case 6: _TRISB6 = 1; break;
 
        case 7: _TRISB7 = 1; break;
 
        case 8: _TRISB8 = 1; break;
 
        case 9: _TRISB9 = 1; break;
 
        case 10: _TRISB10 = 1; break;
 
        case 11: _TRISB11 = 1; break;
 
        case 12: _TRISB12 = 1; break;
 
        case 13: _TRISB13 = 1; break;
 
        case 14: _TRISB14 = 1; break;
 
        default: _TRISB15 = 1;
 
      }
 
      unsigned int mask;
 
      mask = 0x0001 << ch;
 
      ADCSSL = ADCSSL | mask;
 
      ADPCFG = ~ADCSSL;
 
      ADCON2bits.SMPI++; //take one more sample per interrupt
 
  }
 
  void adc_rm_ch(unsigned char ch){
 
      unsigned int mask;
 
      mask = 0x0001 << ch;
 
      ADPCFG = ADPCFG | mask;
 
      ADCSSL = ~ADPCFG;
 
      ADCON2bits.SMPI--; //take one less sample per interrupt
 
  }
 
 
 
----
 
 
 
===EEPROM===
 
*5011 has 1024 bytes of EEPROM, readable and writable under normal voltage (5V).
 
*To use, declare:
 
  unsigned char _EEDATA(2) eeData[1024]={ 0x00, 0x00, 0x00, 0x00, .... }
 
  unsigned int byte_pointer = 0;
 
====Seek====
 
*This function moves the pointer to the desired position before a reading/writing operation is performed.
 
  int eeprom_lseek(int offset, unsigned char whence){
 
      byte_pointer = offset;
 
      return byte_pointer;
 
  }
 
====Read====
 
*This function read ''count'' bytes from the eeprom.
 
  int eeprom_read(unsigned char* buf, int count){
 
      int i=0;
 
      for(; i<count && byte_pointer < 1024; i++){
 
        readEEByte( __builtin_tblpage(eeData),
 
                    __builtin_tbloffset(eeData) + byte_pointer,
 
                    &buf[i]);
 
        byte_pointer++; //Update global pointer
 
      }
 
      return i; //read i bytes successful
 
  }
 
*readEEByte() is implemented in assembly code as follows:
 
  .global _readEEByte
 
  _readEEByte:
 
      push      TBLPAG ;w0 = base of eeData
 
      mov      w0, TBLPAG ;w1 = offset for eeData in byte
 
      tblrdl.b  [w1], [w2] ;w2 = pointer to user buffer
 
      pop    TBLPAG
 
      return
 
 
 
====Write====
 
*This function write ''count'' bytes to eeprom.
 
  int eeprom_write(unsigned char* buf, int count){
 
      char isOddAddr = byte_pointer%2; //current address is odd
 
      char isOddByte = count%2; //number of bytes to write is odd
 
      //=================================================================
 
      unsigned int word_offset = byte_pointer>>1; //div by 2 and round down
 
      int max_write;
 
      max_write = (isOddAddr == 0 && isOddByte == 0) ? (count>>1) : (count>>1)+1;
 
      //=================================================================
 
      unsigned int word_data; //Store word to be written
 
      int byte_wr = 0; //number of bytes written, i.e buffer pointer
 
      int i = 0;
 
      //=================================================================
 
      for(; i<max_write && word_offset<512; i++, word_offset++){
 
        if(i==0 && isOddAddr){
 
            //First byte not used
 
            //============================================save first byte
 
            readEEByte( __builtin_tblpage(eeData),
 
                        __builtin_tbloffset(eeData) + byte_pointer - 1,
 
                        &word_data);
 
            //===========================================================
 
            word_data = ((unsigned int)buf[0] << 8) + (0xFF & word_data);
 
            byte_wr++; //Update buffer pointer
 
            byte_pointer++; //Update global pointer
 
          } else if(i==max_write-1 && ((isOddAddr && sOddByte==0)||(isOddAddr==0 && isOddByte))){
 
            //Last byte not used
 
            //=============================================save last byte
 
            readEEByte( __builtin_tblpage(eeData),
 
                        __builtin_tbloffset(eeData) + byte_pointer + 1,
 
                        &word_data);
 
            //============================================================
 
            word_data = (word_data << 8) + buf[byte_wr];
 
            byte_wr++; //Update buffer pointer
 
            byte_pointer++; //Update global pointer
 
          } else{
 
            //Both bytes valid
 
            word_data = ((unsigned int)buf[byte_wr+1] << 8) + buf[byte_wr];
 
            byte_wr+=2; //Update buffer pointer
 
            byte_pointer+=2; //Update global pointer
 
          }
 
      //==================================================================
 
      eraseEEWord( __builtin_tblpage(eeData),
 
                    __builtin_tbloffset(eeData) + 2*word_offset);
 
      writeEEWord( __builtin_tblpage(eeData),
 
                    __builtin_tbloffset(eeData) + 2*word_offset,
 
                    &word_data);
 
      //==================================================================
 
      }
 
      return byte_wr; //No. of byte written
 
  }
 
*eraseEEWord and writeEEWord are implemented in assembly.
 
  .global _eraseEEWord
 
  .global _writeEEWord
 
  _eraseEEWord:
 
      push  TBLPAG
 
      mov    w0, NVMADRU ;w0 = base of eeData
 
      mov    w1, NVMADR ;w1 = offset for eeData in word
 
      mov    #0x4044, w0
 
      mov    w0, NVMCON ;Set to erase operation
 
      push  SR ;Disable global interrupts
 
      mov    #0x00E0, w0
 
      ior    SR
 
      mov    #0x55, w0 ;Write the KEY sequence
 
      mov    w0, NVMKEY
 
      mov    #0xAA, w0
 
      mov    w0, NVMKEY
 
      bset  NVMCON, #15 ;Start the erase cycle, bit 15 = WR
 
      nop
 
      nop
 
  L1: btsc  NVMCON, #15 ;while(NVMCONbits.WR)
 
      bra    L1
 
      clr    w0
 
      pop    SR ;Enable global interrupts
 
      pop    TBLPAG
 
      return
 
  _writeEEWord:
 
      push  TBLPAG ;w0 = base of eeData
 
      mov    w0, TBLPAG ;w1 = offset for eeData in byte
 
      tblwtl [w2], [w1] ;w2 = pointer to user buffer
 
      mov    #0x4004, w0        ;Set to write operation
 
      MOV    w0, NVMCON
 
      push  SR ;Disable global interrupts
 
      mov    #0x00E0, w0
 
      ior    SR
 
      mov    #0x55, w0 ;Write the KEY sequence
 
      mov    w0, NVMKEY
 
      mov    #0xAA, w0
 
      mov    w0, NVMKEY
 
      bset  NVMCON, #15 ;Start the erase cycle, bit 15 = WR
 
      nop
 
      nop
 
  L2: btsc  NVMCON, #15 ;while(NVMCONbits.WR)
 
      bra    L2
 
      clr    w0
 
      pop    SR ;Enable global interrupts
 
      pop    TBLPAG
 
      return
 
 
 
 
 
----
 
 
 
===DSP Library===
 
*Library functions in <dsp.h> include the following categories:
 
#Vector
 
#Window
 
#Matrix
 
#Filtering
 
#Transform
 
#Control
 
 
 
====Data Types====
 
*Signed Fractional Value (1.15 data format)
 
**Inputs and outputs of the dsp functions adopt 1.15 data format, which consumes 16 bits to represent values between -1 to 1-2<sup>-15</sup> inclusive.
 
**Bit<15> is a signed bit, positive = 0, negative = 1.
 
**Bit<14:0> are the exponent bits ''e''.
 
**Positive value = 1 - 2<sup>-15</sup>*(32768 - ''e'')
 
**Negative value = 0 - 2<sup>-15</sup>*(32768 - ''e'')
 
*40-bit Accumulator operations (9.31 data format)
 
**The dsp functions use the 40 bits accumalators during arithmatic calculations.
 
**Bit<39:31> are signed bits, positive = 0x000, negative = 0x1FF.
 
**Bit<30:0> are exponent bits.
 
*IEEE Floating Point Values
 
**Fractional values can be converted to Floating point values using: '''fo = Fract2Float(fr);''' for fr = [-1, 1-2<sup>-15</sup>]
 
**Floating point values can be converted to Fractional values using: '''fr = Float2Fract(fo);''' or '''fr = Q15(fo);''' for fo = [-1, 1-2<sup>-15</sup>]
 
**Float2Fract() is same as Q15(), except having saturation control. When +ve >= 1, answer = 2<sup>15</sup>-1 = 32767 (0x7FFF). When -ve < -1, answer = -2<sup>15</sup> = -32767 (0x8000)
 
 
 
====Overflow and Saturation Traps====
 
 
 
----
 
 
 
===Build-in Library===
 
*Some assembler operators can only be accessed by inline assembly code, for example,
 
#Manuipulation of accumulators A and B (add, sub, mul, divide, shift, clear, square)
 
#Bit toggling
 
#Access to psv (program space visiblity) page and offset
 
#Access to table instruction page and offset
 
*Built-in functions are written as C-like function calls to utilize these assembler operators.
 
 
 
==Bootloader==
 
 
 
===Concepts===
 
*Programming with ICSP is useful when the target board is produced in batch. The producer can download a program even when the chip is on the target board.
 
*However, ICSP requires an external programmer.
 
*To allow the user to change the program after production but without the need of an external programmer, bootloader becomes useful.
 
*Bootloader is a small program installed via ICSP. Everytime the device is reset, the bootloader is run first. The bootloader first detects the default serial channel whether the user wishes to download a new program to the device. If so, the bootloader will pause there, and wait for the user to download the hex file from the PC. The hex file is written to the device via RTSP instructions in the bootloader. If a new download is not necessary, the bootloader redirects to the previously installed user's program.
 
*The disadvantage of bootloaders is that they consume some of the memory of the device.
 
 
 
 
 
{| border="1" cellspacing="0" cellpadding="5"
 
|+ Table 6.1 Free bootloaders for dsPIC
 
! Developer
 
! Source
 
! Platform
 
! User Guide
 
! Remarks
 
|- valign="top"
 
| [http://www.ingenia-cat.com/index.php?lang=en ingenia]
 
| [http://www.ingenia-cat.com/download/iBL.s Assembly]
 
| [http://www.ingenia-cat.com/download/ingeniadsPICbootloader1.1.zip Windows]
 
| [http://www.ingenia-cat.com/reference/pdf/iBL.UG.V1.2.pdf pdf]
 
|
 
*Works for all dsPIC supporting RTSP
 
*Auto baudrate detection
 
*Use about 1.15% of the flash memory space (0xAFFF-0xAE00)/(0xAFFF-0x0100)
 
*Development of Linux platform is underway
 
*Modification of code for dsPIC30F5011 is successful
 
|-valign="top"
 
| [http://www.etc.ugal.ro/cchiculita/software/picbootloader.htm Tiny]
 
| [http://www.etc.ugal.ro/cchiculita/software/tinybld191.zip Assembly]
 
| Windows
 
| [http://www.etc.ugal.ro/cchiculita/software/tinybldusage.htm Web]
 
|
 
*By default, only supports 601X, 601X, 401X, 2010
 
*Smaller code size than ingenia, but not as easy to modify
 
|-valign="top"
 
| [http://www.via.si/software/dsPIC_bootloader/ Elektronika]
 
| [http://www.via.si/software/dsPIC_bootloader/data/ Hex]
 
| Windows
 
| [http://www.via.si/software/dsPIC_bootloader/data/README.txt txt]
 
|
 
*Only works for dsPIC30F6014 serial port UART2 at baudrate 57600
 
|-
 
|}
 
 
 
===ingenia===
 
====Modification====
 
*For 5011, the bootloader is located between 0x00AE00 to 0x00AFFE (512bytes). Refer to C:\Program Files\Ingenia\ingeniadsPICbootloader\ibl_dspiclist.xml after installing the GUI interface.
 
*Changes made to [http://www.ingenia-cat.com/download/iBL.s assembly code]  includes:
 
1. including p30f5011.gld and p30f5011.inc
 
        .include "p30f5011.inc"
 
2. changing the config code of UART #0x8420 -> #0x8020
 
        ; Uart init
 
        mov '''#0x8020''', W0          ; W0 = 0x8020 -> 1000 0000 0010 0000b
 
        mov W0, U2MODE            ; Enable UART, AutoBaud and 8N1
 
        clr U2STA
 
3. changing the start address 0xAE00 - 0x0100 = 0AD00
 
          .equ CRC, W4
 
          .equ ACK, 0x55
 
          .equ NACK, 0xFF
 
          .equ USER_ADDRESS, 0x0100
 
          .equ START_ADDRESS, '''0xAD00'''                ; Relative to 0x0100
 
4. using Internal FRC and PLL16
 
        config __FOSC, CSW_FSCM_OFF & '''FRC_PLL16''' ;Turn off clock switching and
 
                                          ;fail-safe clock monitoring and
 
                                            ;use the Internal Clock as the
 
                                          ;system clock
 
5. disabling MCLR (optional)
 
        config __FBORPOR, PBOR_ON & BORV_27 & PWRT_16 & '''MCLR_DIS'''
 
                                            ;Set Brown-out Reset voltage and
 
                                            ;and set Power-up Timer to 16msecs
 
6. changing all the related registers of U1ART to U2ART, all U1XXX => U2XXX
 
        '''U2MODE, U2STA, U2BRG, U2RXREG, U2TXREG'''
 
7. changing all the related registers of IC1 to IC2, all IC1XXX => IC2XXX
 
        '''IC2CON, #IC2IF, #IC2IE'''
 
 
 
====Communication Protocol====
 
* Communication Protocol is reviewed in [http://www.ingenia-cat.com/reference/pdf/iBL.UG.V1.2.pdf user's guide] section 2.1.3. The following summarises the key steps on the PC side (Refer also to section 2.2.2).
 
* Transmission is conducted in 8N1, i.e. 8-bit, no parity, 1 stop-bit
 
* '''Stage 1: User's configuation'''
 
**Select a baudrate
 
**Select a COM port channel
 
* '''Stage 2: Autobaud rate detection and version control'''
 
**Continuously sending a character "U" [0x55] via COM port
 
**Continuously waiting for an acknowledgment character "U", [ACK] = [0x55]
 
**Send command character [0x03]
 
**Receive 3 characters 1) Major Version 2) Minor Version 3) Acknowledgment [0x33]
 
**Prints the version number [Major.Minor] (e.g. 1.1) on screen.
 
* '''Stage 3: Loading and writing the program'''
 
**Load the user hex file, check integrity.
 
**Start loading file using:
 
***Read command character [0x01] + 24-bit address [High][Medium][Low]
 
***Receive 4-byte data [High][Medium][Low][ACK]
 
***Write command character [0x02] + 24-bit address [High][Medium][Low]+ Number of bytes [N] + [data 0] + [data 1] + ... + [data N-1] + [CRC]=(INTEL HEX8 Checksum - Sum modulo 256)
 
***Recieve [ACK] or [NACK] = [0xFF]
 
***Note: Writing is in row mode access (i.e. erase and write a whole row, each row has 32 instructions, or 96 bytes because each instruction has 24 bits)
 
::# Ensure the initial address of writing match an initial row position,
 
::# Send the data corresponding to the whole row.
 
 
 
===USB/RS232 Interface===
 
*Window Driver for [http://www.prolific.com.tw/eng/downloads.asp?ID=31 PL-2303 USB to Serial Bridge]
 
*[Java library http://www.rxtx.org/]
 
 
 
 
 
==Programming the Device==
 
 
 
===Requirements===
 
*Hardware
 
#PC with COM port (Windows XP Installed)
 
#ICD2 Programmer
 
#Target Board
 
#5V Power Supply
 
  
*Software
 
#[http://ww1.microchip.com/downloads/en/DeviceDoc/MP750.zip MPLAB IDE v7.50 or higher]
 
#[http://www.ingenia-cat.com/download/ingeniadsPICbootloader1.1.zip ingenia dsPIC bootloader GUI v1.1 or higher]
 
  
*Files
+
==[[Bootloader Development]]==
#Modified ingenia bootloader ('''ingenia.hex'''). Original assembly code can be downloaded from [http://www.ingenia-cat.com/download/iBL.s here].
+
*Description on concepts and development on bootloader
#Application hex file (e.g. '''app.hex''')
+
*Description on dsPicProgrammer to download firmware via bootloader
  
===Procedures===
 
====Loading Bootloader====
 
*Install [http://ww1.microchip.com/downloads/en/DeviceDoc/MP750.zip MPLAB IDE] on PC
 
#Do '''NOT''' connect ICD 2 (via USB) to PC
 
#Execute '''MPLAB vX.XX Install.exe'''
 
*Install USB Driver for ICD 2
 
#Follow the instruction in (C:\Program Files\Microchip\MPLAB IDE\ICD2\Drivers\Ddicd2.htm)
 
*Run MPLAB IDE on PC
 
*Select target chip
 
#Select: Configure>Select Devices...
 
#Choose dsPIC30F5011
 
*Plug-in ICD 2 to PC (USB)
 
#Do '''NOT''' connect target (via 6-pin cable) to ICD 2
 
*Select ICD 2 as the current programmer
 
#Select: Programmer>Select Programmer>MPLAB ICD 2
 
#If this is the first time the ICD 2 is connected to PC, MPLAB IDE will automatically download the required OS to ICD 2, wait until it has finished
 
#You should also see Warnings on invalid device IDs, and/or running self tests. Ignore these warnings since the target board has not been connected yet.
 
*Place Jumper on target board
 
*Connect target board to ICD 2 (via six pin cable)
 
#Beware of the pin assignments. Only pin 1 - 5 should be used.
 
*Power-up the Target
 
*Establish connection with target
 
#On MPLAB IDE, Select Programmer>Connect
 
#See results of self test: Programmer>Settings, Status Tab. Refer to [http://ww1.microchip.com/downloads/en/DeviceDoc/51331B.pdf ICD2 User's Guide] Chapter 7.
 
*Load the bootloader hex file '''ingenia.hex''' on MPLAB IDE
 
#Select: File>Import...
 
*Download the bootloader to target board
 
#Select: Programmer>Program
 
*Power-down the Taget.
 
*Disconnect ICD 2 from PC
 
#Select: Programmer>Select Programmer>None
 
#Unplug USB cable
 
  
====Loading Application====
+
==[[Programming the Device]]==
*Install ingenia dsPIC bootloader GUI on PC
+
*Description on how to use dsPicProgrammer to download firmware to dspic
#Execute '''ingeniadsPICbootloader.exe'''
 
*Connect target board to COM Port
 
*Power-down target board
 
*Run ingenia dsPIC bootloader GUI
 
*Press "OK, my platform is shut down" in Dialog 0
 
*Select COM port and baud rate in Dialog 1
 
*Power-up target board in Dialog 2
 
*Load the '''app.hex''' by pressing Open in Dialog 3
 
*Download the hex file by pressing Write in Dialog 3
 
*Power-down target board and disconnect from COM port
 
  
  
==To Do List==
+
[[category:projects]]
#Explore the possibilities of using USB/RS232 interface
 
#Develop bootloader interface on Linux Platform
 
#Construct examples codes for using DSP library
 
#Construct examples codes for using Build-in library
 
#Review on standard means to access remote and local devices
 

Latest revision as of 06:30, 16 October 2012

This project aims to provide the development tools for building a multi-purpose MCU board. Description is based on Microchip dsPic33FJ256GP506 (was dsPic30F5011), but information provided in this wiki may give useful directions for developing similar embedded systems with different platforms.

Introduction

Features of dsPic33FJ256GP506

  • 3.0 to 3.3 V
  • Up to 40 MIPs
  • Maximum current sink/source for I/O pins: 4 mA
  • 16-bit arithmetics
  • DSP Instruction Set
  • Dual programming techniques: ICSP and RTSP
  • Memory
    • 256 KB flash (86K instructions)
    • 16 KB RAM (incl. 2 KB DMA RAM)
    • No EEPROM
  • Communications ports
    • UART
    • I2C: up to 1 Mbit/s
    • SPI
  • ADC
  • 10-bit A/D, 1.1 Msps
  • 12-bit A/D, 500 ksps
  • No DAC (PWMs only)
  • Pin-to-pin compatible with other dsPICs
Comparison between different dsPICs
dsPic *Price
US$
MIPs Flash
(kB)
RAM
(kB)
EEPROM
(kB)
I/O ADC
12-bit
IC OC Motor
Ctrl
Timers QEI UART SPI I2C CAN Codec
33FJ256GP506 6.11 40 256 16 0 53 18 8 8 0 9x16bit
4x32bit
0 2 2 2 1 1
33FJ128GP206 4.62 40 128 8 0 53 18 8 8 0 9x16bit
4x32bit
0 2 2 1 0 1
33FJ128GP306 4.81 40 128 16 0 53 18 8 8 0 9x16bit
4x32bit
0 2 2 2 0 1
33FJ128GP706 5.49 40 128 16 0 53 18 8 8 0 9x16bit
4x32bit
0 2 2 2 2 1
33FJ128MC506 4.97 40 128 8 0 53 16 8 8 8 9x16bit
4x32bit
1 2 2 2 1 0
33FJ128MC706 5.38 40 128 16 0 53 16 8 8 8 9x16bit
4x32bit
1 2 2 2 1 0

*For reference only, subject to change

Forums

  • Microchip: Official forum by Microchip
    • See MPLAB ICD 2, MPLAB IDE, MPLAB C30 Compiler, ASM30, Link30 forum, dsPIC30F Topics, dsPic33 topics
  • HI-TECH Software Forum: Discussion on dsPICC, a C compiler developed by HI-TECH
  • FreeRTOS Real Time Kernel: Open Discussion and Support on FreeRTOS
  • Nabble: MicroControllers - GNUPIC

References

Code Examples

Related Development


Programming Methods

  • There are 2 programming methods: In-Circuit Serial Programming (ICSP) and Run-Time Self-Programming (RTSP)
  • ICSP allows the devices to be programmed after being placed in a circuit board.
  • RTSP allows the devices to be programmed when an embedded program is already in operation.

ICSP: External Programmer (ICD2)

  • Two types of ICSP are available: ICSP and Enhanced ICSP. Both of them require setting MCLR# to VIHH (9V – 13.25V).
  • Standard ICSP
    • Use external programmer (e.g. MPLAB® ICD 2, MPLAB® PM3 or PRO MATE® II) only.
    • Required low-level programming to erase, program and verify the chip.
    • Slower, because codes are serially executed.
  • Enhanced ICSP
    • Use external programmer and Programming Executive (PE).
    • PE is stored in the on-chip memory.
    • PE allows faster programming.
    • PE can be downloaded to the chip by external programmer using the standard ICSP method.
    • PE contains a small command set to erase, program and verify the chip, avoiding the need of low-level programming.

Hardware Interface

Pin Used by ICSP
Pin Label Function Pin Number
MCLR# Programming Enable 7
VDD Power Supply 10, 26, 38, 57
VSS Ground 9, 25, 41, 56
PGC Serial Clock 17
PGD Serial Data 18


Available Programmers in the Market
Product Name Interface with PC Interface with Device *Price (US) Remarks
MPLAB® ICD 2 USB or RS232 6-PIN RJ-12 connector $159.99 -
Clone Microchip ICD2 (Now Using) USB 6-pin flat cables $52.35 Do not work with new MPLAB versions (works for 7.50), communication to MPLAB may sometime hang (see manual)

*For reference only (exclude shipping), subject to change


DIY ICD 2 Programmer Circuit
Source Schematic PIC16F877A Bootloader
Patrick Touzet Yes HEX
Nebadje Yes Zip


Software Interface

  • The program can be written and compiled in an Integrated Development Environment (IDE) using either Assembly or C. The complied codes are then loaded to the device through the external programmer.
Summary of IDE
Product Name Features OS Price (US$)
MPLAB® IDE Assembler Only Windows Free
MPLAB® C30 Assembler and C-Compiler Windows $895.00 (Free student version1)
Piklab Assembler and C-Compiler Linux Free
  1. Full-featured for the first 60 days. After 60 days, some code optimization functions are disabled. The compiler will continue to function after 60 days, but code size may increase.

RTSP: COM Port (Bootloader)

  • RTSP works in normal voltage (MCLR# no need to raise to VIHH).
  • No literature has mentioned the incorporation of Programming Executive (PE). Presumably, since Enhanced ICSP needs to set MCLR# to VIHH, RTSP cannot use PE.
  • Refer to bootloader section.


Development Environment

Windows

PIC setup win.JPG

  • C-Compiler, Assembler and Linker are under GNU license.
    • MPLAB C30 C Compiler (*.c -> *.s)
    • MPLAB ASM30 Assembler (*.s -> *.o)
    • MPLAB LINK30 Linker (*.o -> *.bin)
  • PA optimizer, simulator, runtime libraries, header files, include files, and linker scripts are not covered by GNU. Reference is here.
  • Microchip has integrated ASM30, LINK30, assembly header files, linker scripts in MPLAB IDE, which is free for download.
  • MPLAB C30 costs US$895. A 60-day free student version is also available. After 60-days, the optimizer is automatically disabled, while other tools can still function properly.


C Libraries in MPLAB C30
Library Directory
(\\Microchip\MPLAB C30)
Major functions
DSP Library
(e.g. libdsp-coff.a)
\lib
\src\dsp
\support\h
Vector, Matrix, Filter, etc.
16-Bit Peripheral Libraries \lib
\src\peripheral
\support\h
ADC12, IOPort, UART, I2C, etc.
Standard C Libraries
(e.g. libc-coff.a, libm-coff.a, libpic-coff.a)
\lib
\src\libm
\include
stdio.h, time.h, float.h, math.h,
MPLAB C30 Built-in Functions none _buildin_addab, _buildin_add, _buildinmpy, etc

Linux

PIC setup linux.JPG

  • C Compiler, Assembler and Linker are under GNU license.
    • The code can be downloaded from Microchip at here.
    • Current MPLAB ASM30 Assembler: v2.04
    • Current MPLAB C30 Compiler: v2.04
  • Important Note: Only the compiler is free. The header files and library are owned by Microchip.
Pic30 C-Compiler Toolchain Templates for Conversion to Debian-based systems
Toolchain Source Instruction Remarks
v2.00 Download pic30-gcc-2.00-1.i386.rpm and pic30-binutils-2.00-1.i386.rpm.
Convert to deb files.
Stable
Now using
v2.05 Reference to example below, but use 2.05 files Can compile
Stable but not heavily tested
v3.01 Follow example below Can compile
Unstable (sometime produce segmentation fault)
v3.10 Reference to example below, but use 3.10 files Cannot compile yet (segmentation fault)

Conversion Example

  • Pre-install these packages: dpkg-dev, debhelper, bison, flex, sysutils, gcc-3.3, fakeroot
    • cmd: sudo apt-get install dpkg-dev debhelper bison flex sysutils gcc-3.3 fakeroot
  • Download and unzip template: pic30-3.01.tar.bz2
  • Download assembler: mplabalc30v3_01_A.tar.gz. Save under /pic30-3.01/pic30-binutils-3.01/upstream/
  • Download c-compiler: mplabc30v3_01_A.tgz. Save under /pic30-3.01/pic30-gcc-3.01/upstream/
  • Install MPLAB_C30_v3_01-StudentEdition under Windows
  • Copy directories /include, /lib, /support, and /bin/c30_device.info to pic30-3.01/pic30-support-3.01/upstream/
  • Pack pic30-binutils into deb file
    • goto /pic30-3.01/pic30-binutils-3.01/
    • type cmd: dpkg-buildpackage -rfakeroot -b
  • Install pic30-binutils_3.01-1_i386.deb
    • type cmd: sudo dpkg -i pic30-binutils_3.01-1_i386.deb
  • Pack pic30-gcc-3.01 into deb file
    • goto /pic30-3.01/pic30-gcc-3.01/
    • type cmd: dpkg-buildpackage -rfakeroot -b
  • Install pic30-gcc_3.01-1_i386.deb
    • type cmd: sudo dpkg -i pic30-gcc_3.01-1_i386.deb
  • Pack support files into deb file
    • goto /pic30-3.01/pic30-support-3.01/
    • type cmd: dpkg-buildpackage -rfakeroot -b
  • Install pic30-support_3.01-1_all.deb
    • type cmd: sudo dpkg -i pic30-support_3.01-1_all.deb
  • After installation, locations of
    • C-Header (*.h): /usr/pic30-elf/include
    • Libraries (*.a): /usr/pic30-elf/lib
    • Assembly header (*.inc): /usr/share/pic30-support/inc
    • Linkerscript (*.gld): /usr/share/pic30-support/gld

Burning Program Codes to Target Board

  1. Use 'dspicprg and dspicdmp' utilities developed by Homer Reid to burn hex code (*.hex) to devices. See Reference here. Through serial port only?
  2. Use Piklab IDE. Details on file format not known.
  3. Use MPLAB IDE to burn hex code (*.hex) to devices.

Code Optimization

  • Below is a comparsion between different optimization levels for the project including drivers for 2 projects.
Comparison between differnt optimization levels
Optimization Description Project 1
Code Size
(byte)
Project 1
Data Usage
(byte)
Project 2
Code Size
(byte)
Project 2
Data Usage
(byte)
O0 No optimization
Fastest Compilation
6222 (9%) 178 (4%) 26,037 (38%) 710 (17%)
O1 Optimize
Tries to reduce code size and execution time.
4473 (6%) 178 (4%) 22,290 (32%) 710 (17%)
O2 Optimize even more
Performs nearly all supported optimizations
that do not involve a space-speed trade-off.
Increases both compilation time and the
performance of the generated code.
4422 (6%) 178 (4%) 21,993 (32%) 710 (17%)
O3 Optimize yet more.
O3 turns on all optimizations specified by O2
and also turns on the inline-functions option.
4485 (6%) 178 (4%) 22,176 (32%) 710 (17%)
Os Optimize for size.
Os enables all O2 optimizations that do not
typically increase code size. It also performs
further optimizations designed to reduce code
size.
4356 (6%) 178 (4%) 21,885 (32%) 710 (17%)


Driver Development

  • Description on developing drivers with POSIX API


Bootloader Development

  • Description on concepts and development on bootloader
  • Description on dsPicProgrammer to download firmware via bootloader


Programming the Device

  • Description on how to use dsPicProgrammer to download firmware to dspic