First CVS-version

This commit is contained in:
Ronald Schaten 2007-01-02 21:30:40 +00:00
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$Id: Changelog.txt,v 1.1 2007/01/02 21:30:39 rschaten Exp $
* Release 07010x
- initial release

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GNU GENERAL PUBLIC LICENSE
Version 2, June 1991
Copyright (C) 1989, 1991 Free Software Foundation, Inc.
59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
Everyone is permitted to copy and distribute verbatim copies
of this license document, but changing it is not allowed.
Preamble
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Also add information on how to contact you by electronic and paper mail.
If the program is interactive, make it output a short notice like this
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Gnomovision version 69, Copyright (C) year name of author
Gnomovision comes with ABSOLUTELY NO WARRANTY; for details type `show w'.
This is free software, and you are welcome to redistribute it
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The hypothetical commands `show w' and `show c' should show the appropriate
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You should also get your employer (if you work as a programmer) or your
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Yoyodyne, Inc., hereby disclaims all copyright interest in the program
`Gnomovision' (which makes passes at compilers) written by James Hacker.
<signature of Ty Coon>, 1 April 1989
Ty Coon, President of Vice
This General Public License does not permit incorporating your program into
proprietary programs. If your program is a subroutine library, you may
consider it more useful to permit linking proprietary applications with the
library. If this is what you want to do, use the GNU Library General
Public License instead of this License.

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# $Id: Makefile,v 1.1 2007/01/02 21:30:39 rschaten Exp $
#
# Creates documentation and tarball for shipping.
TODAY=`date "+%y%m%d"`
DIR=`basename \`pwd\``
PACKETNAME=$(DIR)_$(TODAY)
all: usage
usage:
@echo "Usage of this makefile:"
@echo "make docs create documentation"
@echo "make tarball packs a tarball for shipping"
@echo
@echo "For further information, consult the documentation in Readme.txt."
# doc generation
docs: readme pdf
@echo "documentation created"
readme: doxygen
echo "This file is auto-generated from the content of binarydcf77clock.dox." > Readme.txt
echo "You'll have more fun if you read the HTML-content in htmldoc or the PDF." >> Readme.txt
echo >> Readme.txt
lynx -dump htmldoc/main.html >> Readme.txt
pdf: doxygen
make -C latexdoc
mv latexdoc/refman.pdf .
rm -rf latexdoc
doxygen:
doxygen binarydcf77clock.doxygen
clean:
rm -rf htmldoc latexdoc Readme.txt refman.pdf
rm -f $(PACKETNAME).tar.gz
make -C firmware clean
fw:
make -C firmware
mv -v firmware/main.hex firmware/main_$(TODAY).hex
tarball: fw clean docs
@echo
@echo
@echo "I assume you updated the Changelog...? Press Enter to continue..."
@read
[ -e "firmware/main_$(TODAY).hex" ] || exit
rm --force $(PACKETNAME).tar.gz; \
tar --directory=.. \
--exclude=$(DIR)/Makefile \
--exclude=CVS \
--exclude=*.ps \
--create \
--gzip \
--verbose \
--file ../$(PACKETNAME).tar.gz $(DIR)

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/**
* \mainpage Binary DCF-77 Clock
*
* \section sec_intro Introduction
*
* In Germany, the official time is transmitted in a signal called DCF-77. You
* can find many descriptions of the signal format on the internet.
*
* The Binary DCF-77 Clock is a simple device to receive and decode the signal
* and display the current date and time in binary form. The signal is received
* in a stock DCF-77 receiver module, decoded with an ATmega8 microcontroller
* and displayed in binary form on an array of LEDs. This array consists of for
* lines with eight LEDs each. The ATmega8 is not able to control 32 LEDs at
* once, so an SAA1064 module is used which is connected via I2C-bus.
*
* The time should be displayed in several different binary formats, the format
* can be selected with a simple button. The formats will be described later.
*
* The distribution contains the firmware for the controller, the schematics,
* the documentation and a copy of the GPL license.
*
* \section sec_install Building and installing
*
* The firmware for this project requires avr-gcc and avr-libc (a C-library for
* the AVR controller). Please read the instructions at
* http://www.nongnu.org/avr-libc/user-manual/install_tools.html for how to
* install the GNU toolchain (avr-gcc, assembler, linker etc.) and avr-libc.
*
* Once you have the GNU toolchain for AVR microcontrollers installed, you can
* run "make" in the subdirectory "firmware". You may need to customize the
* makefile. Also, you might have to edit the array byte[] in main.c, which
* describes the order of the output LEDs. The current order works for me
* because I soldered the LEDs as compact as possible, it's slightly different
* from the layout shown in the circuit.
*
* Also, you may have to edit the Makefile to use your preferred downloader
* with "make program". The current version is built for avrdude with a
* USB connection to an avr109-compatible programmer.
*
* No external crystal is needed, so you don't have to struggle with setting
* any fuse-bits.
*
* After making your changes, you can compile and flash to the device:
*
* \code
* make program
* \endcode
*
* \section sec_usage Usage
*
* Connect the device to a DC power source with 9V. As long as no time has been
* decoded, a running light is shown on the output LED array. The single DCF
* indicator LED should start flashing to indicate that a signal is received.
* It is set to on when the input signal is high, and switched off if the
* signal is low. So you should see it flashing with one flash per second, each
* flash being 100ms or 200ms long.
*
* If the signal is received correctly, after about two minutes the clock
* should be able to tell the correct time.
*
* \subsection sec_reading Reading the time
*
* The time and date are displayed in seven different styles. You can select
* the style by pressing the button for a while. A pattern of lights indicate
* which mode is selected, you can read it as a binary value.
*
* \subsubsection sec_mode1 Mode 1: Time as binary
*
* This simply displays the hours, minutes and seconds as bytes, one after
* each other. The fourth line of the display stays blank.
*
* \subsubsection sec_mode2 Mode 2: Date as binary
*
* This is like the previous, with the difference that it displays the day of
* the month, the month and the year in the first three lines. The last line
* shows the day of the week, monday being a 1, tuesday a 2 and so on.
*
* \subsubsection sec_mode3 Mode 3: Time as BCD
*
* This shows the time as binary coded digits (BCD). The first line displays
* the hours. The left four LEDs indicate the 10-hours, the right four LEDs
* indicate the 1-hours.
*
* In the same way, the second and third line display the minutes and the
* seconds.
*
* \subsubsection sec_mode4 Mode 4: Date as BCD
*
* This is like the previous mode, but the date is displayed.
*
* \subsubsection sec_mode5 Mode 5: Time as BCD (vertically)
*
* This shows the time in a BCD-form as described in mode 3, but the BCD-values
* are put vertically next to each other. So in the first two colums you can
* read the hours, the third column is empty, the fourth and fifth columns show
* the minutes, the sixth is empty and the seventh and eighths indicate the
* seconds.
*
* \subsubsection sec_mode6 Mode 6: Date as BCD (vertically)
*
* This is like mode 5, but it displays the date.
*
* \subsubsection sec_mode7 Mode 7: Unix timestamp
*
* This is probably the least human readable format. It shows a 32-bit value of
* the seconds since january 1st, 1970. :-)
*
* \subsection sec_demo Demo mode
*
* If you connect the clock in a place with a poor DCF-reception, but want to
* demonstrate the functions, you can use the demo mode. To toggle this, you
* can touch and hold the button for about five seconds. Afterwards, you can
* switch through the different display modes. The time displayed will stand
* still, so this can be used to explain the display modes without a hurry.
*
* Switching to demo mode is indicated by all LEDs flashing for a short moment.
* Leaving demo mode shows an empty rectangle for a short moment.
*
* \section sec_drawbacks Drawbacks
*
* I didn't expect the DCF-signal to be so easily disturbed. In my case
* sometimes there is no usable signal left when I put my notebook with WLAN
* next to the clock. Fortunately, the time will be counted further until the
* next 'correct minute' is received.
*
* \section sec_files Files in the distribution
*
* - \e Readme.txt: Documentation, created from the htmldoc-directory.
* - \e firmware: Source code of the controller firmware.
* - \e circuit: Circuit diagrams in PDF and EAGLE 4 format. A free version of
* EAGLE is available for Linux, Mac OS X and Windows from
* http://www.cadsoft.de/.
* - \e License.txt: Public license for all contents of this project.
* - \e Changelog.txt: Logfile documenting changes in firm- and hardware.
* - \e refman.pdf: Full documentation of the software.
*
* \section sec_thanks Thanks!
*
* I'd like to thank <b>Michael Meier</b>, who developed and published a much
* more sophisticated clock on his site. The SAA1064-stuff and the routine to
* calculate the Unix timestamp are based on his project. You can find it under
* http://www.mulder.franken.de/ntpdcfledclock/.
*
* And once again I'd like to give special credits to <b>Thomas Stegemann</b>
* for help with the C language.
*
* \section sec_license About the license
*
* Our work - all contents except for the USB driver - are licensed under the
* GNU General Public License (GPL). A copy of the GPL is included in
* License.txt. The driver itself is licensed under a special license by
* Objective Development. See firmware/usbdrv/License.txt for further info.
*
* <b>(c) 2006 by Ronald Schaten - http://www.schatenseite.de</b>
*/

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EAGLE Version 4.16r1 Copyright (c) 1988-2006 CadSoft
Electrical Rule Check for /home/rschaten/microcontroller/binarydcf77clock/circuit/circuit.sch at 12/30/2006 10:30:30
WARNING: Sheet 1/1: POWER Pin IC2 VEE connected to GND
ERROR: 8 OUTPUT Pins on net B$1
ERROR: 8 OUTPUT Pins on net B$2
No board loaded - consistency has not been checked
2 errors
1 warnings

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Partlist
Exported from circuit.sch at 12/30/2006 10:40:23
EAGLE Version 4.16r1 Copyright (c) 1988-2006 CadSoft
Part Value Device Package Library Sheet
C1 100n C-EU025-024X044 C025-024X044 rcl 1
C2 100n C-EU025-024X044 C025-024X044 rcl 1
C3 470u CPOL-EUE5-8.5 E5-8,5 rcl 1
C4 100n C-EU025-024X044 C025-024X044 rcl 1
C5 2,7n C-EU025-024X044 C025-024X044 rcl 1
C6 100n C-EU025-024X044 C025-024X044 rcl 1
IC1 MEGA8-P MEGA8-P DIL28-3 avr 1
IC2 SAA1064 SAA1064 DIL24-6 micro-philips 1
IC3 MC7805CT 7805T TO220H linear 1
JP1 ISP JP5Q JP5Q jumper 1
JP2 DCF77 JP4E JP4 jumper 1
JP3 JP1E JP1 jumper 1
LED1 LED3MM LED3MM led 1
LED2 LED3MM LED3MM led 1
LED3 LED3MM LED3MM led 1
LED4 LED3MM LED3MM led 1
LED5 LED3MM LED3MM led 1
LED6 LED3MM LED3MM led 1
LED7 LED3MM LED3MM led 1
LED8 LED3MM LED3MM led 1
LED9 LED3MM LED3MM led 1
LED10 LED3MM LED3MM led 1
LED11 LED3MM LED3MM led 1
LED12 LED3MM LED3MM led 1
LED13 LED3MM LED3MM led 1
LED14 LED3MM LED3MM led 1
LED15 LED3MM LED3MM led 1
LED16 LED3MM LED3MM led 1
LED17 LED3MM LED3MM led 1
LED18 LED3MM LED3MM led 1
LED19 LED3MM LED3MM led 1
LED20 LED3MM LED3MM led 1
LED21 LED3MM LED3MM led 1
LED22 LED3MM LED3MM led 1
LED23 LED3MM LED3MM led 1
LED24 LED3MM LED3MM led 1
LED25 LED3MM LED3MM led 1
LED26 LED3MM LED3MM led 1
LED27 LED3MM LED3MM led 1
LED28 LED3MM LED3MM led 1
LED29 LED3MM LED3MM led 1
LED30 LED3MM LED3MM led 1
LED31 LED3MM LED3MM led 1
LED32 LED3MM LED3MM led 1
LED33 LED3MM LED3MM led 1
Q2 BC547 BC547 TO92 transistor-npn 1
Q3 BC547 BC547 TO92 transistor-npn 1
R1 10k R-EU_0207/10 0207/10 rcl 1
R3 1k R-EU_0207/10 0207/10 rcl 1
S1 31-XX B3F-31XX switch-omron 1

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# $Id: Makefile,v 1.1 2007/01/02 21:30:40 rschaten Exp $
# microcontroller settings
F_CPU = 1000000UL
MCU = atmega8
AVRDUDE = avrdude -p $(MCU) -P /dev/parport0 -c stk200 -E noreset,vcc
AVRDUDE = avrdude -p $(MCU) -P /dev/tts/USB0 -b 115200 -c avr109
COMPILE = avr-gcc -Wall -Os -I../common -I. -mmcu=$(MCU) -DF_CPU=$(F_CPU) #-DDEBUG_LEVEL=2
OBJECTS = saa1064.o dcftime.o main.o
# symbolic targets:
all: main.hex
.c.o:
$(COMPILE) -c $< -o $@
.S.o:
$(COMPILE) -x assembler-with-cpp -c $< -o $@
# "-x assembler-with-cpp" should not be necessary since this is the default
# file type for the .S (with capital S) extension. However, upper case
# characters are not always preserved on Windows. To ensure WinAVR
# compatibility define the file type manually.
.c.s:
$(COMPILE) -S $< -o $@
program: all
$(AVRDUDE) -U flash:w:main.hex
clean:
rm -f main.hex main.lst main.obj main.cof main.list main.map main.eep.hex main.bin *.o main.s
# file targets:
main.bin: $(OBJECTS)
$(COMPILE) -o main.bin $(OBJECTS)
main.hex: main.bin
rm -f main.hex main.eep.hex
avr-objcopy -j .text -j .data -O ihex main.bin main.hex
disasm: main.bin
avr-objdump -d main.bin
cpp:
$(COMPILE) -E main.c

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#ifndef BOOLE_H
#define BOOLE_H
/**
* \file boole.h
* \brief Simple boolean variables
* \author Thomas Stegemann
* \version $Id: boole.h,v 1.1 2007/01/02 21:30:40 rschaten Exp $
*
* License: See documentation.
*/
enum boolean_enum { False = 0, True = 1 };
typedef enum boolean_enum boolean;
static inline boolean boole(int test) {
if (test == 0) {
return False;
} else {
return True;
}
}
static inline const char *boolean_name(boolean value) {
if (value == False) {
return "false";
} else {
return "true";
}
}
#endif /* BOOLE_H */

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/**
* \file dcftime.c
* \brief Decoder for DCF-77 time signals
* \author Ronald Schaten & Thomas Stegemann
* \version $Id: dcftime.c,v 1.1 2007/01/02 21:30:40 rschaten Exp $
*
* License: See documentation.
*/
#include "boole.h"
#include "dcftime.h"
// TODO: define and use meaningful states for certain situations (valid time, no values received, etc.)
// TODO: find correct start of the seconds. ATM the clock is running late by one second
// TODO: check if it is possible to give DCF_RATE as parameter for init()
typedef unsigned int dcf_sample; /**< number of the current sample */
typedef unsigned int dcf_sizetype; /**< used for the size of a month */
const dcf_sample dcf_second_samples = (DCF_RATE); /**< number of samples per second */
/** dcf signal between 30ms and 130ms => dcf logic false (lower value) */
const dcf_sample dcf_logic_false_min = (DCF_RATE)*3/100;
/** dcf signal between 30ms and 130ms => dcf logic false (upper value) */
const dcf_sample dcf_logic_false_max = (DCF_RATE)*13/100;
/** dcf signal between 140ms and 230ms => dcf logic true (lower value) */
const dcf_sample dcf_logic_true_min = (DCF_RATE)*14/100;
/** dcf signal between 140ms and 230ms => dcf logic true (upper value) */
const dcf_sample dcf_logic_true_max = (DCF_RATE)*23/100;
/** duration between begin of dcf second (== begin of signal), should be 1 * second +/- 3% (lower value) */
const dcf_sample dcf_second_tolerance_min = (DCF_RATE) - (DCF_RATE)*3/100;
/** duration between begin of dcf second (== begin of signal), should be 1 * second +/- 3% (upper value) */
const dcf_sample dcf_second_tolerance_max = (DCF_RATE) + (DCF_RATE)*3/100;
/** definition of logical signal states */
enum dcf_logic_signal_enum {
dcf_signal_no, /**< no signal */
dcf_signal_false, /**< 'false' signal */
dcf_signal_true, /**< 'true' signal */
dcf_signal_invalid /**< invalid signal */
};
/** definition of logical signal states */
typedef enum dcf_logic_signal_enum dcf_logic_signal;
/** format of the received data, filled during reception */
struct dcf_receiving_data_struct {
dcf_date date; /**< date */
dcf_time time; /**< time */
boolean parity; /**< parity of the received data */
boolean is_valid; /**< data is valid */
dcf_logic_signal current_signal; /**< logical state of the received data */
dcf_sample low_samples; /**< counts low signal samples per second */
dcf_sample high_samples; /**< counts high signal samples per second */
};
/** definition of the received data, filled during reception */
typedef struct dcf_receiving_data_struct dcf_receiving_data;
/** format of the DCF data.
* dcf_current_datetime() and dcf_sample() may be called from different contexts. To avoid changing the current_datetime while it is read:
* if use_first_current_datetime is true: dcf_current_datetime reads current_datetime[0] and dcf_sample changes current_datetime[1]
* if use_first_current_datetime is false: vice versa
*/
struct dcf_data_struct {
dcf_datetime current_datetime[2]; /**< two full datasets */
boolean use_first_current_datetime; /**< flag if the first or the second dataset is used */
dcf_sample current_datetime_sample; /**< number of the current sample */
dcf_receiving_data receiving_data; /**< data being filled */
};
/*
global data
*/
static struct dcf_data_struct dcf_data; /**< full set of received dcf data */
/*
dcf_time
*/
/**
* Initialize a dcf_time value.
* \param pTime: pointer to a dcf_time variable
*/
static void dcf_time_init(dcf_time * pTime) {
pTime->second = 0;
pTime->minute = 0;
pTime->hour = 0;
pTime->is_dst = False;
}
/**
* Increment a time-value by one second.
* \param pTime: pointer to a dcf_time variable
* \return True if the date has to be incremented, too. Otherwise False.
*/
static boolean dcf_time_inc(dcf_time * pTime) {
++(pTime->second);
if (pTime->second == 60) {
pTime->second = 0;
++(pTime->minute);
if (pTime->minute == 60) {
pTime->minute = 0;
++(pTime->hour);
if (pTime->hour == 24) {
pTime->hour = 0;
return True; /* overflow => increment date */
}
}
}
return False;
}
/**
* Check if a time-value makes sense.
* \param pTime: pointer to a dcf_time variable
* \return True if the time is logically correct. Otherwise False.
*/
static boolean dcf_time_is_valid(dcf_time * pTime) {
return (pTime->second <= 60)
&& (pTime->minute <= 60)
&& (pTime->hour <= 24);
}
/*
dcf_date
*/
/**
* Initialize a dcf_date value.
* \param pDate: pointer to a dcf_date variable
*/
static void dcf_date_init(dcf_date * pDate) {
pDate->dayofweek = dcf_sunday;
pDate->dayofmonth = 1;
pDate->month = dcf_january;
pDate->year = 0;
}
/**
* Calculate the number of days in a month.
* \param pDate: pointer to a dcf_time variable
* \return The number of days in the given month.
*/
static dcf_sizetype dcf_date_days_in_month(dcf_date * pDate) {
switch (pDate->month) {
case dcf_february:
if (pDate->year % 4 != 0)
return 28; /* year not divisible by 4 */
else if (pDate->year != 0)
return 29; /* year divisible by 4 and not divisible by 100 */
else if (((pDate->dayofmonth % 7) + 1) != pDate->dayofweek)
return 28; /* year divisible by 100 and not divisible by 400 */
else
return 29; /* year divisible by 400 */
/*
if year is divisble by 400 (eg year 2000) the 1st february is a tuesday (== 2 (== 1+1))
if year divided by 400 remains 100 1st February is a monday
if year divided by 400 remains 200 1st February is a saturday
if year divided by 400 remains 300 1st February is a thursday
this repeats every 400 years, because 400 year are 3652425/25 day
which is 7*521775/25, therefore divisible by 7
which means every 400 years the day of week are the same
! dayofmonth and dayofweek must be synchronized to get the right value
*/
case dcf_april:
case dcf_june:
case dcf_september:
case dcf_november:
return 30;
default:
return 31;
}
}
/**
* Increment a date-value by one day.
* \param pDate: pointer to a dcf_date variable
*/
static void dcf_date_inc(dcf_date * pDate) {
++(pDate->dayofweek);
if (pDate->dayofweek == 8) {
pDate->dayofweek = 1;
}
++(pDate->dayofmonth);
if (pDate->dayofmonth == (dcf_date_days_in_month(pDate) + 1)) {
pDate->dayofmonth = 1;
++(pDate->month);
if (pDate->month == 13) {
pDate->month = 1;
++(pDate->year);
if (pDate->year == 100) {
pDate->year = 0;
}
}
}
}
/**
* Check if a date-value makes sense.
* \param pDate: pointer to a dcf_date variable
* \return True if the date is logically correct. Otherwise False.
*/
static boolean dcf_date_is_valid(dcf_date * pDate) {
return (1 <= pDate->dayofweek)
&& (pDate->dayofweek <= 7)
&& (1 <= pDate->dayofmonth)
&& (pDate->dayofmonth <= dcf_date_days_in_month(pDate))
&& (1 <= pDate->month)
&& (pDate->month <= 12)
&& (pDate->year <= 99);
}
/*
dcf_datetime
*/
/**
* Initialize a dcf_datetime value.
* \param pDatetime: pointer to a dcf_datetime variable
*/
static void dcf_datetime_init(dcf_datetime * pDatetime) {
pDatetime->is_valid = False;
pDatetime->has_signal = False;
dcf_time_init(&(pDatetime->time));
dcf_date_init(&(pDatetime->date));
}
/**
* Increment a datetime-value by one second.
* \param pDatetime: pointer to a dcf_datetime variable
*/
static void dcf_datetime_inc(dcf_datetime * pDatetime) {
if (dcf_time_inc(&(pDatetime->time))) {
dcf_date_inc(&(pDatetime->date));
}
}
/*
dcf_receiving_data
*/
/**
* Initialize a dcf_receiving_data value.
* \param pReceive: pointer to a dcf_receiving_data variable
*/
static void dcf_receiving_data_init(dcf_receiving_data * pReceive) {
pReceive->current_signal = dcf_signal_no;
pReceive->parity = False;
pReceive->is_valid = True;
pReceive->low_samples = 0;
pReceive->high_samples = 0;
dcf_time_init(&(pReceive->time));
dcf_date_init(&(pReceive->date));
}
/**
* Calculate the time and date while the bits are received.
* \param signal: True if the received bit is 200ms, False if the bit is 100ms.
*/
static void dcf_logic(boolean signal) {
dcf_data.receiving_data.parity ^= signal;
switch (dcf_data.receiving_data.time.second) {
case 16: dcf_data.receiving_data.parity = True; break;
case 17: dcf_data.receiving_data.time.is_dst = signal; break;
case 18: if(dcf_data.receiving_data.parity) dcf_data.receiving_data.is_valid = False; break;
case 19: dcf_data.receiving_data.parity = True; break;
case 20: if(!signal) dcf_data.receiving_data.is_valid = False; break;
case 21: dcf_data.receiving_data.time.minute = signal ? 1 : 0; break;
case 22: dcf_data.receiving_data.time.minute += signal ? 2 : 0; break;
case 23: dcf_data.receiving_data.time.minute += signal ? 4 : 0; break;
case 24: dcf_data.receiving_data.time.minute += signal ? 8 : 0; break;
case 25: dcf_data.receiving_data.time.minute += signal ? 10 : 0; break;
case 26: dcf_data.receiving_data.time.minute += signal ? 20 : 0; break;
case 27: dcf_data.receiving_data.time.minute += signal ? 40 : 0; break;
case 28: if(dcf_data.receiving_data.parity) dcf_data.receiving_data.is_valid = False; break;
case 29: dcf_data.receiving_data.time.hour = signal ? 1 : 0; break;
case 30: dcf_data.receiving_data.time.hour += signal ? 2 : 0; break;
case 31: dcf_data.receiving_data.time.hour += signal ? 4 : 0; break;
case 32: dcf_data.receiving_data.time.hour += signal ? 8 : 0; break;
case 33: dcf_data.receiving_data.time.hour += signal ? 10 : 0; break;
case 34: dcf_data.receiving_data.time.hour += signal ? 20 : 0; break;
case 35: if(dcf_data.receiving_data.parity) dcf_data.receiving_data.is_valid = False; break;
case 36: dcf_data.receiving_data.date.dayofmonth = signal ? 1 : 0; break;
case 37: dcf_data.receiving_data.date.dayofmonth += signal ? 2 : 0; break;
case 38: dcf_data.receiving_data.date.dayofmonth += signal ? 4 : 0; break;
case 39: dcf_data.receiving_data.date.dayofmonth += signal ? 8 : 0; break;
case 40: dcf_data.receiving_data.date.dayofmonth += signal ? 10 : 0; break;
case 41: dcf_data.receiving_data.date.dayofmonth += signal ? 20 : 0; break;
case 42: dcf_data.receiving_data.date.dayofweek = signal ? 1 : 0; break;
case 43: dcf_data.receiving_data.date.dayofweek += signal ? 2 : 0; break;
case 44: dcf_data.receiving_data.date.dayofweek += signal ? 4 : 0; break;
case 45: dcf_data.receiving_data.date.month = signal ? 1 : 0; break;
case 46: dcf_data.receiving_data.date.month += signal ? 2 : 0; break;
case 47: dcf_data.receiving_data.date.month += signal ? 4 : 0; break;
case 48: dcf_data.receiving_data.date.month += signal ? 8 : 0; break;
case 49: dcf_data.receiving_data.date.month += signal ? 10 : 0; break;
case 50: dcf_data.receiving_data.date.year = signal ? 1 : 0; break;
case 51: dcf_data.receiving_data.date.year += signal ? 2 : 0; break;
case 52: dcf_data.receiving_data.date.year += signal ? 4 : 0; break;
case 53: dcf_data.receiving_data.date.year += signal ? 8 : 0; break;
case 54: dcf_data.receiving_data.date.year += signal ? 10 : 0; break;
case 55: dcf_data.receiving_data.date.year += signal ? 20 : 0; break;
case 56: dcf_data.receiving_data.date.year += signal ? 40 : 0; break;
case 57: dcf_data.receiving_data.date.year += signal ? 80 : 0; break;
case 58: if(dcf_data.receiving_data.parity) dcf_data.receiving_data.is_valid = False; break;
}
++(dcf_data.receiving_data.time.second);
}
/**
* Copy the values from receiving_data to current_datetime.
*/
static void dcf_store(void) {
if ((dcf_data.receiving_data.is_valid)
&& dcf_time_is_valid(&(dcf_data.receiving_data.time))
&& dcf_date_is_valid(&(dcf_data.receiving_data.date))) {
dcf_data.current_datetime_sample = 0;
if (dcf_data.use_first_current_datetime) {
dcf_data.current_datetime[1].time = dcf_data.receiving_data.time;
dcf_data.current_datetime[1].date = dcf_data.receiving_data.date;
dcf_data.current_datetime[1].is_valid = True;
dcf_data.use_first_current_datetime = False;
} else {
dcf_data.current_datetime[0].time = dcf_data.receiving_data.time;
dcf_data.current_datetime[0].date = dcf_data.receiving_data.date;
dcf_data.current_datetime[0].is_valid = True;
dcf_data.use_first_current_datetime = True;
}
}
}
/**
* Copy valid time and increment it.
*/
static void dcf_inc(void) {
if (dcf_data.use_first_current_datetime) {
dcf_data.current_datetime[1] = dcf_data.current_datetime[0];
dcf_datetime_inc(&(dcf_data.current_datetime[1]));
dcf_data.use_first_current_datetime = False;
} else {
dcf_data.current_datetime[0] = dcf_data.current_datetime[1];
dcf_datetime_inc(&(dcf_data.current_datetime[0]));
dcf_data.use_first_current_datetime = True;
}
}
/*
exported functions, documented in header file
*/
void dcf_init(void) {
dcf_data.use_first_current_datetime = True;
dcf_data.current_datetime_sample = 0;
dcf_datetime_init(&(dcf_data.current_datetime[0]));
dcf_datetime_init(&(dcf_data.current_datetime[1]));
dcf_receiving_data_init(&(dcf_data.receiving_data));
}
void dcf_signal(boolean signal) {
if (dcf_data.receiving_data.low_samples > dcf_second_samples) {
if (dcf_data.receiving_data.time.second == 59) {
dcf_data.receiving_data.time.second = 0;
dcf_store();
} else {
dcf_data.receiving_data.time.second = 0;
}
dcf_data.receiving_data.low_samples = 0;
dcf_data.receiving_data.is_valid = True;
}
/* calculate receiving date time */
if (signal) {
dcf_data.receiving_data.low_samples = 0;
++(dcf_data.receiving_data.high_samples);
} else {
++(dcf_data.receiving_data.low_samples);
if (dcf_data.receiving_data.high_samples == 0) {
} else if (dcf_data.receiving_data.high_samples < dcf_logic_false_min) {
/* too short signal */
dcf_data.receiving_data.is_valid = False;
dcf_data.receiving_data.current_signal = dcf_signal_invalid;
} else if (dcf_data.receiving_data.high_samples < dcf_logic_false_max) {
/* short signal, logic 0 */
dcf_logic(False);
dcf_data.receiving_data.current_signal = dcf_signal_false;
} else if (dcf_data.receiving_data.high_samples < dcf_logic_true_min) {
/* signal cannot be assigned to true or false */
dcf_data.receiving_data.is_valid = False;
dcf_data.receiving_data.current_signal = dcf_signal_invalid;
} else if (dcf_data.receiving_data.high_samples < dcf_logic_true_max) {
/* long signal, logic 1 */
dcf_logic(True);
dcf_data.receiving_data.current_signal = dcf_signal_true;
} else {
/* too long signal */
dcf_data.receiving_data.is_valid = False;
dcf_data.receiving_data.current_signal = dcf_signal_invalid;
}
dcf_data.receiving_data.high_samples = 0;
}
/* calculate current date time */
++(dcf_data.current_datetime_sample);
if (dcf_data.current_datetime_sample == dcf_second_samples) {
dcf_data.current_datetime_sample = 0;
dcf_inc();
}
}
dcf_datetime dcf_current_datetime(void) {
if (dcf_data.use_first_current_datetime) {
dcf_data.current_datetime[0].has_signal = dcf_data.receiving_data.is_valid;
return dcf_data.current_datetime[0];
} else {
dcf_data.current_datetime[1].has_signal = dcf_data.receiving_data.is_valid;
return dcf_data.current_datetime[1];
}
}
const char *dcf_dayofweek_name(dcf_dayofweek dow) {
switch (dow) {
case 1:
return "Mo";
case 2:
return "Tu";
case 3:
return "We";
case 4:
return "Th";
case 5:
return "Fr";
case 6:
return "Sa";
case 7:
return "Su";
default:
return "??";
}
}
const char *dcf_is_dst_name(dcf_is_dst dst) {
if (dst) {
return "ST";
} else {
return "WT";
}
}

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#ifndef DCFTIME_H
#define DCFTIME_H
/**
* \file dcftime.h
* \brief Decoder for DCF-77 time signals
* \author Ronald Schaten & Thomas Stegemann
* \version $Id: dcftime.h,v 1.1 2007/01/02 21:30:40 rschaten Exp $
*
* License: See documentation.
*/
#include "boole.h"
/*
dcf-signal samples per second
*/
#ifndef DCF_RATE
#define DCF_RATE 244 /**< number of samples per second. dcf_signal() should be called this often */
#endif
#if (DCF_RATE < 100) || (250 < DCF_RATE)
#error DCF_RATE should be between 100 and 250
#endif
typedef unsigned int dcf_second; /**< seconds (0-59) */
typedef unsigned int dcf_minute; /**< minutes (0-59) */
typedef unsigned int dcf_hour; /**< hours (0-24) */
typedef unsigned int dcf_dayofmonth; /**< day of month (1-31) */
typedef unsigned int dcf_year; /**< year (0-99) */
typedef boolean dcf_is_dst; /**< daylight saving: True: MESZ, False: MEZ */
/** definition of weekdays */
enum dcf_dayofweek_enum {
dcf_monday = 1, /**< monday = 1 */
dcf_tuesday, /**< tuesday */
dcf_wednesday, /**< wednesday */
dcf_thursday, /**< thursday */
dcf_friday, /**< friday */
dcf_saturday, /**< saturday */
dcf_sunday, /**< sunday = 7 */
};
/** definition of weekdays */
typedef enum dcf_dayofweek_enum dcf_dayofweek;
/** definition of months */
enum dcf_month_enum {
dcf_january = 1, /**< january = 1 */
dcf_february, /**< february */
dcf_march, /**< march */
dcf_april, /**< april */
dcf_may, /**< may */
dcf_june, /**< june */
dcf_july, /**< july */
dcf_august, /**< august */
dcf_september, /**< september */
dcf_october, /**< october */
dcf_november, /**< november */
dcf_december /**< december = 12 */
};
/** definition of months */
typedef enum dcf_month_enum dcf_month;
/** format of the dcf_time */
struct dcf_time_struct {
dcf_second second; /**< seconds */
dcf_minute minute; /**< minutes */
dcf_hour hour; /**< hours */
dcf_is_dst is_dst; /**< daylight saving time */
};
/** definition of dcf_time */
typedef struct dcf_time_struct dcf_time;
/** format of the dcf_date */
struct dcf_date_struct {
dcf_dayofweek dayofweek; /**< day of week */
dcf_dayofmonth dayofmonth; /**< day of month */
dcf_month month; /**< month */
dcf_year year; /**< year */
};
/** definition of dcf_date */
typedef struct dcf_date_struct dcf_date;
/** format of the dcf_datetime */
struct dcf_datetime_struct {
dcf_time time; /**< the time */
dcf_date date; /**< the time */
boolean is_valid; /**< if is_valid is False: no complete signal received, do not use date and times */
boolean has_signal; /**< if has_signal is True: currently receiving signal */
};
/** definition of dcf_datetime */
typedef struct dcf_datetime_struct dcf_datetime;
/**
* Initialize the DCF-module. Call dcf_init before any other DCF function.
*/
void dcf_init(void);
/**
* Tell the DCF-module if the signal is high or low. This function decides if
* the received bit is a long or a short one, and if it is usable at all. It
* should be called regularly, the number of calls per second is defined in
* DCF_RATE.
* \param signal: True if the input signal is high, False if it is low.
*/
void dcf_signal(boolean signal);
/**
* Fetch the current date and time.
* \return The current date and time in a dcf_datetime structure
*/
dcf_datetime dcf_current_datetime(void);
/**
* Get the name of the current weekday.
* \param dow: Day of the current week. Monday = 1, tuesday = 2...
* \return Pointer to the name
*/
const char* dcf_dayofweek_name(dcf_dayofweek dow);
/**
* Get the name of the current daylight saving time (summertime, wintertime).
* \param dst: daylight saving time bit from the time signal
* \return Pointer to the name
*/
const char* dcf_is_dst_name(dcf_is_dst dst);
#endif

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/**
* \file main.c
* \brief Firmware for the binary DCF-77 clock
* \author Ronald Schaten
* \version $Id: main.c,v 1.1 2007/01/02 21:30:40 rschaten Exp $
*
* License: See documentation.
*/
#include <avr/io.h>
#include <avr/interrupt.h>
#include <avr/pgmspace.h>
#include <util/delay.h>
#include "saa1064.h"
#include "dcftime.h"
uint8_t byte[4] = { 2, 3, 1, 0 }; /** the order of the connected output-LED-rows */
uint8_t output[4], outputOld[4]; /** current and old content of the LEDs */
/** the display-modes */
enum modes {
timeasbinary,
dateasbinary,
timeasbcdhorizontal,
dateasbcdhorizontal,
timeasbcdvertical,
dateasbcdvertical,
timestamp
};
enum modes mode;
uint8_t demomode = 0;
/**
* sends the current content of output[] to the LEDs if it has changed.
*/
void setLeds(void) {
uint8_t i;
for (i = 0; i < 4; i++) {
if (output[i] != outputOld[i]) {
set_led_digit(byte[i], output[i]);
outputOld[i] = output[i];
}
}
} // function setLeds
/**
* Takes the current time and converts it into different output-formats.
* \param datetime: the current time
*/
void setOutput(dcf_datetime datetime) {
uint8_t bcdlow, bcdhigh; /* takes the low and high parts when converting to BCD */
const uint32_t TS01012000 = 946681200UL; /* The UNIX-Timestamp of 1.1.2000 */
const uint16_t monthstarts[12] = { 0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334 }; /* On which day does a new month start in non-leap-years */
const uint32_t SECONDSINADAY = (60UL * 60 * 24); /* Number of seconds in a day */
uint32_t ts; /* takes the UNIX-Timestamp */
switch (mode) {
case timeasbinary:
/* hour, minute and second are displayed in rows */
output[0] = datetime.time.hour;
output[1] = datetime.time.minute;
output[2] = datetime.time.second;
output[3] = 0;
break;
case dateasbinary:
/* day of month, month, year and day of week (starting with monday
* = 1) are displayed in rows */
output[0] = datetime.date.dayofmonth;
output[1] = datetime.date.month;
output[2] = datetime.date.year;
output[3] = datetime.date.dayofweek;
break;
case timeasbcdhorizontal:
/* the time is converted to BCD, the digits are displayed by two in
* a row */
bcdlow = datetime.time.hour % 10;
bcdhigh = datetime.time.hour / 10;
output[0] = (bcdhigh << 4) | bcdlow;
bcdlow = datetime.time.minute % 10;
bcdhigh = datetime.time.minute / 10;
output[1] = (bcdhigh << 4) | bcdlow;
bcdlow = datetime.time.second % 10;
bcdhigh = datetime.time.second / 10;
output[2] = (bcdhigh << 4) | bcdlow;
output[3] = 0;
break;
case dateasbcdhorizontal:
/* the date is converted to BCD, the digits are displayed by two in
* a row */
bcdlow = datetime.date.dayofmonth % 10;
bcdhigh = datetime.date.dayofmonth / 10;
output[0] = (bcdhigh << 4) | bcdlow;
bcdlow = datetime.date.month % 10;
bcdhigh = datetime.date.month / 10;
output[1] = (bcdhigh << 4) | bcdlow;
bcdlow = datetime.date.year % 10;
bcdhigh = datetime.date.year / 10;
output[2] = (bcdhigh << 4) | bcdlow;
bcdlow = datetime.date.dayofweek;
bcdhigh = 0;
output[3] = (bcdhigh << 4) | bcdlow;
break;
case timeasbcdvertical:
/* the time is converted to BCD, the digits are displayed in
* columns */
output[0] = 0;
output[1] = 0;
output[2] = 0;
output[3] = 0;
bcdlow = datetime.time.hour % 10;
bcdhigh = datetime.time.hour / 10;
output[0] |= ((bcdhigh & 8) << 4) | ((bcdlow & 8) << 3);
output[1] |= ((bcdhigh & 4) << 5) | ((bcdlow & 4) << 4);
output[2] |= ((bcdhigh & 2) << 6) | ((bcdlow & 2) << 5);
output[3] |= ((bcdhigh & 1) << 7) | ((bcdlow & 1) << 6);
bcdlow = datetime.time.minute % 10;
bcdhigh = datetime.time.minute / 10;
output[0] |= ((bcdhigh & 8) << 1) | ((bcdlow & 8) << 0);
output[1] |= ((bcdhigh & 4) << 2) | ((bcdlow & 4) << 1);
output[2] |= ((bcdhigh & 2) << 3) | ((bcdlow & 2) << 2);
output[3] |= ((bcdhigh & 1) << 4) | ((bcdlow & 1) << 3);
bcdlow = datetime.time.second % 10;
bcdhigh = datetime.time.second / 10;
output[0] |= ((bcdhigh & 8) >> 2) | ((bcdlow & 8) >> 3);
output[1] |= ((bcdhigh & 4) >> 1) | ((bcdlow & 4) >> 2);
output[2] |= ((bcdhigh & 2) << 0) | ((bcdlow & 2) >> 1);
output[3] |= ((bcdhigh & 1) << 1) | ((bcdlow & 1) << 0);
break;
case dateasbcdvertical:
/* the date is converted to BCD, the digits are displayed in
* columns */
output[0] = 0;
output[1] = 0;
output[2] = 0;
output[3] = 0;
bcdlow = datetime.date.dayofmonth % 10;
bcdhigh = datetime.date.dayofmonth / 10;
output[0] |= ((bcdhigh & 8) << 4) | ((bcdlow & 8) << 3);
output[1] |= ((bcdhigh & 4) << 5) | ((bcdlow & 4) << 4);
output[2] |= ((bcdhigh & 2) << 6) | ((bcdlow & 2) << 5);
output[3] |= ((bcdhigh & 1) << 7) | ((bcdlow & 1) << 6);
bcdlow = datetime.date.month % 10;
bcdhigh = datetime.date.month / 10;
output[0] |= ((bcdhigh & 8) << 1) | ((bcdlow & 8) << 0);
output[1] |= ((bcdhigh & 4) << 2) | ((bcdlow & 4) << 1);
output[2] |= ((bcdhigh & 2) << 3) | ((bcdlow & 2) << 2);
output[3] |= ((bcdhigh & 1) << 4) | ((bcdlow & 1) << 3);
bcdlow = datetime.date.year % 10;
bcdhigh = datetime.date.year / 10;
output[0] |= ((bcdhigh & 8) >> 2) | ((bcdlow & 8) >> 3);
output[1] |= ((bcdhigh & 4) >> 1) | ((bcdlow & 4) >> 2);
output[2] |= ((bcdhigh & 2) << 0) | ((bcdlow & 2) >> 1);
output[3] |= ((bcdhigh & 1) << 1) | ((bcdlow & 1) << 0);
break;
case timestamp:
/* compute the UNIX-Timestamp. This function is based on http://www.mulder.franken.de/ntpdcfledclock/ */
ts = TS01012000 + SECONDSINADAY; /* 2000 was leap year */
ts += SECONDSINADAY * datetime.date.year * 365;
/* Now account for the leap years. Yes, 2000 was a leap year too. */
ts += SECONDSINADAY * ((datetime.date.year - 1) / 4);
ts += SECONDSINADAY * monthstarts[datetime.date.month - 1];
if (((datetime.date.year % 4) == 0) && (datetime.date.month > 2)) {
/* We are in a leap year and past february */
ts += SECONDSINADAY;
}
ts += SECONDSINADAY * (datetime.date.dayofmonth - 1);
ts += 3600UL * datetime.time.hour;
ts += 60 * datetime.time.minute;
ts += datetime.time.second;
output[0] = (ts >> 24);
output[1] = (ts >> 16);
output[2] = (ts >> 8);
output[3] = (ts >> 0);
break;
default:
break;
}
} // function setOutput
/**
* Sets the output to a running light. This is used when no valid time can be
* displayed.
*/
void setWaiting(void) {
static uint8_t position = 0;
output[0] = 0;
output[1] = 0;
output[2] = 0;
output[3] = 0;
if (position < 8) {
output[0] = (1 << position);
} else if (position == 8) {
output[1] = 128;
} else if (position == 9) {
output[2] = 128;
} else if (position == 18) {
output[2] = 1;
} else if (position == 19) {
output[1] = 1;
} else {
output[3] = (128 >> (position - 10));
}
position++;
if (position > 19) {
position = 0;
}
} // function setWaiting
/**
* Timer interrupt function. This is called on every timer-interrupt (which
* happens 488 times per second.
*/
void timerInterrupt(void) {
dcf_datetime datetime; /** takes the current time and date */
static uint8_t tickcounter; /** internal tick, is incremented with every timer-loop */
static uint8_t keycounter = 0; /** used to defeat bouncing buttons */
static uint8_t demomodecounter = 0; /** used to switch to demo mode */
static uint8_t modeswitched = 0; /** set when the mode has been switched, displays bars to indicate the new mode. */
tickcounter++;
/* on every second interrupt, check the state of the DCF-signal */
if (tickcounter % 2) {
if ((PINC & (1 << PINC0))) {
// signal high
dcf_signal(True);
PORTC |= (1 << PINC1);
} else {
// signal low
dcf_signal(False);
PORTC &= ~(1 << PINC1);
}
}
/* on every 32nd interrupt, check if the key is pressed. After 5 loops with
* a pressed key, switch to the next display-mode. */
if (tickcounter % 32 == 0) {
if (!(PINC & (1 << PINC2))) {
// key pressed
keycounter++;
if (keycounter > 4) {
// after 4 cycles with pressed key, switch to the next mode
keycounter = 0;
mode++;
if (mode > timestamp) {
mode = timeasbinary;
}
modeswitched = 5;
}
demomodecounter++;
if (demomodecounter > 75) {
// after 75 cycles with pressed key, switch to or from demo mode
if (demomode == 0) {
demomode = 1;
mode = timeasbinary;
output[0] = 255;
output[1] = 255;
output[2] = 255;
output[3] = 255;
} else {
demomode = 0;
mode = timeasbinary;
output[0] = 255;
output[1] = 129;
output[2] = 129;
output[3] = 255;
}
setLeds();
demomodecounter = 0;
}
} else {
// key unpressed
keycounter = 0;
demomodecounter = 0;
}
}
/* on every 128th interrupt (about 4 times per second), check if anything
* new has to be displayed. */
if (tickcounter % 128 == 0) {
if (demomode == 1) {
// set the current date and time to a fixed value to demonstrate
// how the time is displayed
datetime.is_valid = 1;
datetime.time.hour = 10;
datetime.time.minute = 35;
datetime.time.second = 10;
datetime.date.dayofmonth = 30;
datetime.date.month = 12;
datetime.date.year = 6;
datetime.date.dayofweek = 6;
} else {
datetime = dcf_current_datetime();
}
if (modeswitched > 0) {
output[0] = mode + 1;
output[1] = mode + 1;
output[2] = mode + 1;
output[3] = mode + 1;
modeswitched--;
} else if (datetime.is_valid) {
setOutput(datetime);
} else {
setWaiting();
}
/* finally, set the output */
setLeds();
}
} // function timerInterrupt
/**
* Main-function. Initializes the hardware and starts the main loop of the
* application.
* \return An integer. Whatever... :-)
*/
int main(void) {
uint8_t i;
/* set a default display-mode */
mode = timeasbinary;
/* intialize ports */
DDRC = (1 << DDC1); // set pin 1 to output
PORTC = (1 << PC1) | (1 << PC2); // activate pullups on pins 1 and 2
/* initialize SAA1064 on i2c-bus */
led_init();
set_led_brightness(1);
for (i = 0; i <= 3; i++) { /* switch off all connected LEDs */
set_led_digit(i, 0);
}
/* initialize DCF77 */
dcf_init();
/* initialize timer */
TCCR0 = (0 << CS02) | (1 << CS01) | (0 << CS00); // set divider to 8.
/* The interrupt is called every 8*256 CPU-cycles, at 1MHz we get 488
* calls per second. DCF_RATE in dcftime.h has to be set according to
* this value. */
sei();
while (1) { /* main event loop */
if (TIFR & (1 << TOV0)) {
TIFR |= 1 << TOV0; /* clear pending flag */
timerInterrupt();
}
}
return 0;
}

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/**
* \file saa1064.c
* \brief I2C-connection to the SAA1064 LED-driver
* \author Ronald Schaten
* \version $Id: saa1064.c,v 1.1 2007/01/02 21:30:40 rschaten Exp $
*
* License: See documentation.
*/
/* based on http://www.mulder.franken.de/ntpdcfledclock/ */
#include <avr/io.h>
#include <util/delay.h>
#include "saa1064.h"
/* The Port used for the connection */
#define LEDPORT PORTC
#define LEDPIN PINC
#define LEDDDR DDRC
/* Which pins of the port */
#define SDAPIN PC4
#define SCLPIN PC5
/* the I2C addresses of the SAA 1064 LED drivers */
#define SAA_AD1 0x70 // or 0x76?
#define I2C_READ 0x01
#define I2C_WRITE 0x00
/* Should be at least 27 (80 / 3) at 8 MHz */
/* This was the conservative value used for testing. However, half as much should work as well. */
#define DELAYVAL 3
void led_init(void) {
/* activate pullups */
LEDPORT |= (1 << SCLPIN) | (1 << SDAPIN);
}
/* Send START, defined as high-to-low SDA with SCL high.
* Expects SCL and SDA to be high already!
* Returns with SDA and SCL low. */
static void I2C_start(void) {
/* Change to output mode. */
LEDDDR |= (1 << SDAPIN) | (1 << SCLPIN);
/* change SDA to low */
LEDPORT &= ~(1 << SDAPIN);
_delay_loop_1(DELAYVAL);
/* and SCL too */
LEDPORT &= ~(1 << SCLPIN);
_delay_loop_1(DELAYVAL);
}
/* Send STOP, defined as low-to-high SDA with SCL high.
* Expects SCL and SDA to be low already!
* Returns with SDA and SCL high. */
static void I2C_stop(void) {
/* Set SCL */
LEDPORT |= (1 << SCLPIN);
_delay_loop_1(DELAYVAL);
/* Set SDA */
LEDPORT |= (1 << SDAPIN);
_delay_loop_1(DELAYVAL);
/* Probably safer to tristate the bus */
LEDDDR &= ~((1 << SDAPIN) | (1 << SCLPIN));
}
/* Transmits the byte in what.
* Returns 1 if the byte was ACKed, 0 if not.
* Expects SCL and SDA to be low already!
* Returns with SDA and SCL low. */
static uint8_t I2C_transmit_byte(uint8_t what) {
uint8_t i;
for (i = 0; i < 8; i++) {
/* First put data on the bus */
if (what & 0x80) {
LEDPORT |= (1 << SDAPIN);
}
_delay_loop_1(DELAYVAL);
/* Then set SCL high */
LEDPORT |= (1 << SCLPIN);
_delay_loop_1(DELAYVAL);
/* Take SCL back */
LEDPORT &= ~(1 << SCLPIN);
_delay_loop_1(DELAYVAL);
/* And SDA too */
LEDPORT &= ~(1 << SDAPIN);
_delay_loop_1(DELAYVAL);
what <<= 1;
}
/* OK that was the data, now we read back the ACK */
/* We need to tristate SDA for that */
LEDPORT |= (1 << SDAPIN);
LEDDDR &= ~(1 << SDAPIN);
/* Give the device some time */
_delay_loop_1(DELAYVAL);
_delay_loop_1(DELAYVAL);
_delay_loop_1(DELAYVAL);
/* Then set SCL high */
LEDPORT |= (1 << SCLPIN);
_delay_loop_1(DELAYVAL);
_delay_loop_1(DELAYVAL);
_delay_loop_1(DELAYVAL);
i = LEDPIN & (1 << SDAPIN); /* Read ACK */
/* Take SCL back */
LEDPORT &= ~(1 << SCLPIN);
_delay_loop_1(DELAYVAL);
/* No more tristate, we pull SDA again */
LEDPORT &= ~(1 << SDAPIN);
LEDDDR |= (1 << SDAPIN);
_delay_loop_1(DELAYVAL);
return (i == 0);
}
void set_led_digit(uint8_t digit, uint8_t val) {
I2C_start();
/* Address device */
I2C_transmit_byte(SAA_AD1 | I2C_WRITE);
I2C_transmit_byte((digit & 3) + 1); /* Address Digit Register on device */
I2C_transmit_byte(val); /* Send value for Digit */
I2C_stop();
}
void set_led_brightness(uint8_t led_brightness) {
I2C_start();
I2C_transmit_byte(SAA_AD1 | I2C_WRITE); /* Address first driver */
I2C_transmit_byte(0); /* Address Config Register on device */
I2C_transmit_byte(((led_brightness & 0x07) << 4) | 0x07); /* Send Settings */
I2C_stop();
}

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#ifndef _SAA1064_H_
#define _SAA1064_H_
/**
* \file saa1064.h
* \brief I2C-connection to the SAA1064 LED-driver
* \author Ronald Schaten
* \version $Id: saa1064.h,v 1.1 2007/01/02 21:30:40 rschaten Exp $
*
* License: See documentation.
*/
/* based on http://www.mulder.franken.de/ntpdcfledclock/ */
/* This sets one digit on the LED module.
* digit is the number of the digit (0 - 7)
* val is a bitfield that contains the values to set. */
void set_led_digit(uint8_t digit, uint8_t val);
/* Configures the brightness of the LED module, or rather: the current the driver allows through them.
* The values 0 through 7 can be used, corresponding to 0 through 21 mA */
void set_led_brightness(uint8_t led_brightness);
/* Initialize the LED module... This basically enables the pullups on the I2C Bus pins */
void led_init(void);
#endif