Difference between revisions of "User Interface"

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[[File:RPi-UI.jpg|thumb|300px|alt=The RPi_UI PCB|The RPi_UI PCB]]
[[File:RPi-UI.jpg|thumb|300px|alt=The RPi_UI PCB|The RPi_UI PCB]]


This is the documentation page for the RPi_UI board.
This is the documentation page for the RPi_UI board. That can be found in the [http://www.bitwizard.nl/shop/index.php?route=product/search&search=user%20interface BitWizard shop].


== Overview ==


== Assembly instructions ==


== Specifications ==
== Installation ==
See [[bw_tool#Setting up I2C/SPI under Linux | Setting up I2C/SPI under Linux]]


=== Possible Configurations ===


== External resources ==
== External resources ==
Line 22: Line 20:
== Additional software ==
== Additional software ==


The [[Bw_tool]] is meant to provide a basic commandline access to the bitwizard expansion boards

=== Related projects ===




Line 42: Line 39:
| 3 || GND
| 3 || GND
|}
|}


Some people report they find it difficult to read the names of the connectors on the PCB. We'll fix that in a future version. In the meanwhile:
[[File:Rpi_ui_docu.png|none|thumb|500px|alt=The RPi_UI PCB|The RPi_UI PCB]]

Note that for the 20x4 version of the board, the connectors are in the same order with the same pinout.


=== LEDs ===
=== LEDs ===
Line 47: Line 50:
The only LED is a power indicator.
The only LED is a power indicator.


== jumper settings ==
== Jumper settings ==


There is one 2x2 pin jumper (JP1), which controls which SPI bus (actually which SPI chip-select line) is routed to the AVRs slave-select pin, and which is routed to the reset pin (to enable reprogramming of the AVR):<br>
There is one 2x2 pin jumper (JP1), which controls which SPI bus (actually which SPI chip-select line) is routed to the AVRs slave-select pin, and which is routed to the reset pin (to enable reprogramming of the AVR):<br>
Line 54: Line 57:
Bottom pads/pins connected: SPI0 connected to RESET
Bottom pads/pins connected: SPI0 connected to RESET
Top (near the LCD) pads/pins connected: SPI1 connected to Slave-Select
Top (near the LCD) pads/pins connected: SPI1 connected to Slave-Select

The recommended configuration is to have 1-3 connected. The pins 1 and 2 are marked on the PCB. So 1-3 means the jumper is closest to the board edge, running from the "1" to the "J" of "JP1".

People with the buttons/LCD on I2C can/should not install any jumpers here.


There is also one solder jumper, SJ1, which controls the supply voltage on the SPI, I2C, and UART connectors:<br>
There is also one solder jumper, SJ1, which controls the supply voltage on the SPI, I2C, and UART connectors:<br>
1-2: 5V (left)<br>
1-2: 5V (left)<br>
2-3: 3V3 (right, near the PCB edge)
2-3: 3V3 (right, near the PCB edge)

We deliver this jumper in the "5V" position with a small PCB trace. If you want to switch to 3.3V you'll have to cut the small trace with a knife.


== Protocol ==
== Protocol ==
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To make the RPI_UI PCB do things, you need to send things over the SPI or I2C bus to the PCB. A comparison of the two protocols can be found [[SPI_versus_I2C_protocols|here]].
To make the RPI_UI PCB do things, you need to send things over the SPI or I2C bus to the PCB. A comparison of the two protocols can be found [[SPI_versus_I2C_protocols|here]].


The general overview of the SPI protocol is [[General_SPI_protocol|here]].
The general overview of the SPI protocol is [[General_SPI_protocol|here]].

the list of the default addresses is [[Default_addresses|here]].


== The software ==
== The software ==
Line 69: Line 80:
Controlling the display works the same way as our SPI_LCD or I2C_LCD modules. Reading the pushbuttons is very much like the DIO module. The read and write ports are described below.
Controlling the display works the same way as our SPI_LCD or I2C_LCD modules. Reading the pushbuttons is very much like the DIO module. The read and write ports are described below.


=== write ports ===
=== Write ports ===


Some ports just set a single value. So writing more than one byte to such a port is redundant. Other ports are logically a stream of bytes. So writing more than one byte is encouraged.
Some ports just set a single value. So writing more than one byte to such a port is redundant. Other ports are logically a stream of bytes. So writing more than one byte is encouraged.
Line 80: Line 91:
|-
|-
| 0x01 || write data as command to LCD.
| 0x01 || write data as command to LCD.
|-
| 0x08 || Set startup message line 1. After setting the startup message please wait 100ms before sending the next line. works from version 1.6+
|-
| 0x09 || Set startup message line 2.
|-
| 0x0a || Set startup message line 3.
|-
| 0x0b || Set startup message line 4.
|-
|-
| 0x10 || any data clears the screen.
| 0x10 || any data clears the screen.
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| 0x13 || set backlight.
| 0x13 || set backlight.
|-
|-
| 0x14 || reinit LCD. The initialzation procedure of the LCD takes a long time. A timed delay of about 500ms is in order after issuing this command
| 0x14 || reinit LCD.
|-
|-
| 0x15 || send 0 to set overrun-status back to zero.
|-
| 0x17 || Set the boot-time backlight intensity. (0xff means: use programmed default (0xc0))
|-
| 0x20 || set display number-of-lines. These are passed on to the display software, but seem to have little effect.
|-
| 0x21 || set display number-of-characters.
|-

| 0x70 .. 0x71 || Select which i/o is coupled to which ADC channel
| 0x70 .. 0x71 || Select which i/o is coupled to which ADC channel
|-
|-
| 0x80 || Set number of ADC channels to read
| 0x80 || Set number of ADC channels to read
|-
|-
| 0x81 || Set number of samples to add (we suggest using a power of 2) (two bytes)
| 0x81 || Set number of samples to add (we suggest using a power of 2) (two bytes) See: [[annoying bug]]
|-
|-
| 0x82 || Set ammounts of bits to shift accumulated sample value
| 0x82 || Set ammounts of bits to shift accumulated sample value
|-
|-
| 0xf0 || change address.
| 0xf0 || change address. But need to unlock first. See below. <br> Might require a reboot to take effect.
|-
| 0xf1 || change address: unlock phase 1: write 0x55 here to start unlocking.
|-
| 0xf2 || change address: unlock phase 2: write 0xaa here to allow changing of the address (after writing 0x55 to f1).
|}
|}


=== read ports ===
=== Read ports ===
The rpi_ui board supports several read ports:
The rpi_ui board supports several read ports:


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|-
|-
| 0x02 || read eeprom (serial number).
| 0x02 || read eeprom (serial number).
|-
| 0x12 || contrast
|-
| 0x13 || backlight intensity
|-
| 0x15 || read FIFO(first in, first out) overrun status. If different from previous value, you've had an overrun. Best to
clear the screen and resend any data you want displayed.
|-
| 0x16 || read FIFO bytes-in-buffer. The fifo is 32 bytes, So you can send 20 chars to display if the value is less than 12.
|-
| 0x17 || read stored backlight intensity.
|-
|-
| 0x20 || read button 1 (1 means NOT pushed, 0 means pushed)
| 0x20 || read button 1 (1 means NOT pushed, 0 means pushed)
Line 185: Line 228:


== Using the RTC ==
== Using the RTC ==

We first designed the User Interface to be equipped with either an SPI RTC or an I2C RTC. In practice the driver for the i2c version was a lot easier, so we're not selling the ones with the SPI RTC unless you really, really want (and we haven't run out of boards by then).


=== I2C ===
=== I2C ===
Line 190: Line 235:
The I2C RTC has a Linux driver, which is available in the standard kernels delivered with raspian. (and probably others too).
The I2C RTC has a Linux driver, which is available in the standard kernels delivered with raspian. (and probably others too).


Just issue:
Just use:
modprobe i2c:mcp7941x
modprobe i2c:mcp7941x
echo mcp7941x 0x6f > /sys/class/i2c-dev/i2c-0/device/new_device
echo mcp7941x 0x6f > /sys/class/i2c-dev/i2c-1/device/new_device
and the module is loaded and detects the RTC.
and the module is loaded and detects the RTC.


You can then set the RTC with: "hwclock -w". This will write the unix clock to the RTC. Put a "hwclock -s" somewhere in your startup scripts to initialize the unix clock from the RTC.
You can then set the RTC with: "hwclock -w". This will write the unix clock to the RTC. Put a "hwclock -s" somewhere in your startup scripts to initialize the unix clock from the RTC.
The version 1 raspberry pi's had the i2c-0 bus on the gpio connector, you for the older raspberry pi you'll need to change i2c-1 into i2c-0..


= examples =
=== SPI ===


We are not aware of a device driver for the SPI version of the RTC. We can read/write the RTC with bw_tool from the command line using the raw SPI bytes command line option "--hex". The CPU on the board has to enable the CS line for the SPI RTC. This limits the speed of the SPI transactions a bit (50 kHz has been verified working).
== read identification ==

bw_tool -s 50000 --hex 96 12 20 1 2 34 5 6 7 89

will write (0x12) the test-bytes 1 2 34 5 6 7 89 to the RAM at location 0x20 in the RAM.

bw_tool -s 50000 --hex 96 13 20 0 0 0 0 0 0 0 0

will read them back.

Refer to the datasheet of the MCP79522 for information on the registers of the chip http://ww1.microchip.com/downloads/en/DeviceDoc/22300A.pdf

= Examples =

== Read identification ==


read the identification string of the board.
read the identification string of the board.
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|}
|}


== set cursor position ==
== Set cursor position ==
move to line 1, character 5:
move to line 1, character 5:
{| border=1
{| border=1
Line 252: Line 312:
|}
|}


== Bash script to show system informations ==
== Default operation ==


== Future hardware enhancements ==



This bash script shows the current time and load averages of the cpu. The refresh is set to 5 seconds.
== Future software enhancements ==


#!/bin/bash
# What display to use:
DISPL="bw_tool -I -D /dev/i2c-1 -a 94"
# e.g. for SPI use:
#DISPL="bw_tool -D /dev/spidev1.0 -a 94"
#clean the display
$DISPL -W 10:0:b
while true; do
#get cpu loads
load=`cut -d' ' -f-3 /proc/loadavg`
#print the current time
$DISPL -W 11:00:b
$DISPL -t `date +%H:%M:%S`
#print the load averages
$DISPL -W 11:20:b
$DISPL -t $load
#idle for 5 seconds
sleep 5
done


== Changelog ==
== Changelog ==

Latest revision as of 16:02, 14 January 2016

The RPi_UI PCB
The RPi_UI PCB

This is the documentation page for the RPi_UI board. That can be found in the BitWizard shop.


Installation

See Setting up I2C/SPI under Linux


External resources

Datasheets

Additional software

The Bw_tool is meant to provide a basic commandline access to the bitwizard expansion boards


Pinout

The 26 pin gpio connector is described at elinux
The SPI connector has the same pinout as the atmel 6-pin ICSP connector and is documented here: SPI_connector_pinout.
The I2C connector is documented here: I2C_connector_pinout.
The UART connector is documented here: uart connector pinout.
The analog connector has the following pinout:

pin function
1 5V
2 Analog in
3 GND


Some people report they find it difficult to read the names of the connectors on the PCB. We'll fix that in a future version. In the meanwhile:

The RPi_UI PCB
The RPi_UI PCB

Note that for the 20x4 version of the board, the connectors are in the same order with the same pinout.

LEDs

The only LED is a power indicator.

Jumper settings

There is one 2x2 pin jumper (JP1), which controls which SPI bus (actually which SPI chip-select line) is routed to the AVRs slave-select pin, and which is routed to the reset pin (to enable reprogramming of the AVR):
Left pads/pins connected: SPI0 connected to Slave-Select Right pads/pins connected: SPI1 connected to RESET Bottom pads/pins connected: SPI0 connected to RESET Top (near the LCD) pads/pins connected: SPI1 connected to Slave-Select

The recommended configuration is to have 1-3 connected. The pins 1 and 2 are marked on the PCB. So 1-3 means the jumper is closest to the board edge, running from the "1" to the "J" of "JP1".

People with the buttons/LCD on I2C can/should not install any jumpers here.

There is also one solder jumper, SJ1, which controls the supply voltage on the SPI, I2C, and UART connectors:
1-2: 5V (left)
2-3: 3V3 (right, near the PCB edge)

We deliver this jumper in the "5V" position with a small PCB trace. If you want to switch to 3.3V you'll have to cut the small trace with a knife.

Protocol

To make the RPI_UI PCB do things, you need to send things over the SPI or I2C bus to the PCB. A comparison of the two protocols can be found here.

The general overview of the SPI protocol is here.

the list of the default addresses is here.

The software

Controlling the display works the same way as our SPI_LCD or I2C_LCD modules. Reading the pushbuttons is very much like the DIO module. The read and write ports are described below.

Write ports

Some ports just set a single value. So writing more than one byte to such a port is redundant. Other ports are logically a stream of bytes. So writing more than one byte is encouraged.

The rpi_ui board defines several ports.

port function
0x00 display data.
0x01 write data as command to LCD.
0x08 Set startup message line 1. After setting the startup message please wait 100ms before sending the next line. works from version 1.6+
0x09 Set startup message line 2.
0x0a Set startup message line 3.
0x0b Set startup message line 4.
0x10 any data clears the screen.
0x11 move the cursor to line l, position p.
l is the top 3 bits
p is the bottom 5 bits of the data.
0x12 set contrast.
0x13 set backlight.
0x14 reinit LCD. The initialzation procedure of the LCD takes a long time. A timed delay of about 500ms is in order after issuing this command
0x15 send 0 to set overrun-status back to zero.
0x17 Set the boot-time backlight intensity. (0xff means: use programmed default (0xc0))
0x20 set display number-of-lines. These are passed on to the display software, but seem to have little effect.
0x21 set display number-of-characters.
0x70 .. 0x71 Select which i/o is coupled to which ADC channel
0x80 Set number of ADC channels to read
0x81 Set number of samples to add (we suggest using a power of 2) (two bytes) See: annoying bug
0x82 Set ammounts of bits to shift accumulated sample value
0xf0 change address. But need to unlock first. See below.
Might require a reboot to take effect.
0xf1 change address: unlock phase 1: write 0x55 here to start unlocking.
0xf2 change address: unlock phase 2: write 0xaa here to allow changing of the address (after writing 0x55 to f1).

Read ports

The rpi_ui board supports several read ports:

port function
0x01 identification string. (terminated with 0).
0x02 read eeprom (serial number).
0x12 contrast
0x13 backlight intensity
0x15 read FIFO(first in, first out) overrun status. If different from previous value, you've had an overrun. Best to

clear the screen and resend any data you want displayed.

0x16 read FIFO bytes-in-buffer. The fifo is 32 bytes, So you can send 20 chars to display if the value is less than 12.
0x17 read stored backlight intensity.
0x20 read button 1 (1 means NOT pushed, 0 means pushed)
0x21 read button 2 (1 means NOT pushed, 0 means pushed)
0x22 read button 3 (1 means NOT pushed, 0 means pushed)
0x23 read button 4 (1 means NOT pushed, 0 means pushed)
0x24 read button 5 (1 means NOT pushed, 0 means pushed)
0x25 read button 6 (1 means NOT pushed, 0 means pushed)
0x30 reports which buttons have been pushed since last read of this register

If you keep a button pushed, it will read out as 1 multiple times

0x31 reports which buttons have been pushed since last read of this register (V1.2 and up)

If you keep a button pushed, it will read out as 1 only once

0x40 read button 1 (1 means pushed, 0 means NOT pushed) (V1.1 and up)
0x41 read button 2 (1 means pushed, 0 means NOT pushed) (V1.1 and up)
0x42 read button 3 (1 means pushed, 0 means NOT pushed) (V1.1 and up)
0x43 read button 4 (1 means pushed, 0 means NOT pushed) (V1.1 and up)
0x44 read button 5 (1 means pushed, 0 means NOT pushed) (V1.1 and up)
0x45 read button 6 (1 means pushed, 0 means NOT pushed) (V1.1 and up)
0x60.. 0x61 Return analog value (2 bytes)
0x68 .. 0x69 Return added and bitshifted analog value (2 bytes)
0x70 .. 0x71 Return which i/o is coupled to which ADC channel
0x80 Return number of ADC channels to read
0x81 Return number of samples to add (two bytes)
0x82 Return ammounts of bits to shift accumulated sample value

Using the analog inputs

Please see this chapter on the page explaining the DIO protocol. There are two major differences:

  • The internal reference voltage needs to be configured in a different way
  • The mapping of the analog inputs; please use the following table instead:
IO pin value
temp 0xC7 (Vref=1V1) OR 0x47 (Vref=Vcc=~5V)
ext 0xC6 (Vref=1V1) OR 0x46 (Vref=Vcc=~5V)

Example

Setup the ADC (only needed once after reboot):

bw_tool -a 94 -w 70:c7 //Set ADC channel 0 to temperature sensor, and internal 1V1 reference
bw_tool -a 94 -w 80:01 //Set number of channels to sample to 1

Read the value:

bw_tool -a 94 -R 60:s // Read the result, output in hex

Using the temperature sensor

The temperature sensor is a MCP9700. It's output voltage depends on the temperature. For more information, please see the MCP9700 datasheet.

An initialization and readout script are available on the Temperature sensor example page.

Using the RTC

We first designed the User Interface to be equipped with either an SPI RTC or an I2C RTC. In practice the driver for the i2c version was a lot easier, so we're not selling the ones with the SPI RTC unless you really, really want (and we haven't run out of boards by then).

I2C

The I2C RTC has a Linux driver, which is available in the standard kernels delivered with raspian. (and probably others too).

Just use:

modprobe i2c:mcp7941x
echo mcp7941x 0x6f > /sys/class/i2c-dev/i2c-1/device/new_device

and the module is loaded and detects the RTC.

You can then set the RTC with: "hwclock -w". This will write the unix clock to the RTC. Put a "hwclock -s" somewhere in your startup scripts to initialize the unix clock from the RTC. The version 1 raspberry pi's had the i2c-0 bus on the gpio connector, you for the older raspberry pi you'll need to change i2c-1 into i2c-0..

SPI

We are not aware of a device driver for the SPI version of the RTC. We can read/write the RTC with bw_tool from the command line using the raw SPI bytes command line option "--hex". The CPU on the board has to enable the CS line for the SPI RTC. This limits the speed of the SPI transactions a bit (50 kHz has been verified working).

 bw_tool -s 50000 --hex 96 12 20 1 2 34 5 6 7 89

will write (0x12) the test-bytes 1 2 34 5 6 7 89 to the RAM at location 0x20 in the RAM.

 bw_tool -s 50000 --hex 96 13 20 0 0 0 0 0 0 0 0

will read them back.

Refer to the datasheet of the MCP79522 for information on the registers of the chip http://ww1.microchip.com/downloads/en/DeviceDoc/22300A.pdf

Examples

Read identification

read the identification string of the board.

data sent data recieved explanation
0x95 xx select destination with address 0x94 for READ.
0x01 xx identify
xx 0x73 's'
xx 0x70 'p'
xx 0x69 'i'
xx ... etc.

Send text to display

Display the string "Hello World!" (only the first 5 bytes of the string shown).

data sent data recieved explanation
0x94 xx select destination with address 0x94 for WRITE
0x00 xx datastream
0x48 xx 'H'
0x65 xx 'e'
0x6c xx 'l'
0x6c xx 'l'
0x6f xx 'o'
xx ... etc.

Set cursor position

move to line 1, character 5:

data sent data recieved explanation
0x94 xx select destination with address 0x94 for WRITE
0x11 xx port 0x11 = set cursor position.
0x25 xx 0x25 = 001 00101 = line 1 position 5.

Bash script to show system informations

This bash script shows the current time and load averages of the cpu. The refresh is set to 5 seconds.

#!/bin/bash

# What display to use: 
DISPL="bw_tool -I -D /dev/i2c-1 -a 94"
# e.g. for SPI use: 
#DISPL="bw_tool -D /dev/spidev1.0 -a 94"

#clean the display
$DISPL -W 10:0:b

while true; do
       #get cpu loads
       load=`cut -d' ' -f-3 /proc/loadavg`
   
       #print the current time 
       $DISPL -W 11:00:b
       $DISPL -t `date +%H:%M:%S`

       #print the load averages
       $DISPL -W 11:20:b
       $DISPL -t $load

       #idle for 5 seconds
       sleep 5
done

Changelog

1.0

  • Initial public release