Difference between revisions of "Dual Display station - software description"
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: o Sent on A-B wires (speaker). | : o Sent on A-B wires (speaker). | ||
: o Signal levels: (Note: The station itself consumes 10mA (1) at all times, which is included in the values below) | : o Signal levels: (Note: The station itself consumes 10mA (1) at all times, which is included in the values below) | ||
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|width="100pt" |Handset OFF: | |width="100pt" |Handset OFF: | ||
Revision as of 09:08, 14 August 2007
Contents
Coding conventions
Software configuration: Using #define settings
By setting or removing #define precompiler statements, pieces of code can be easily added or removed. One example of this is enabling or disabling all debug functionality in a release:
- #define DEBUG_ENABLED
All such statements are collected in the top of the file <main.h>.
Loading C strings from FLASH
The IAR C compiler for AVR processors is by default configured for reading strings from DATA segment (RAM). This requires the compiler to copy the strings from FLASH to RAM during initialisation/cstartup. After that, the stings can be used in normal "ANSI C style":
- printf("Hello World!");
Loading the strings to RAM is required for the strings to be manipulated during run-time. But by using special-designed functions instead of printf(), this can be avoided. Printing strings is done with a separate function, which loads text from FLASH only.
This could be achieved by pre-defining all strings:
- BYTE flash *string_example = "Hello World!";
... and it would be used this way:
- print_string(string_example);
This is not an easy code to read. Instead, the string could be used the normal way by making a few configurations:
- The CSTR segment containing strings is configured as a CODE segment (FLASH) in the linker file <lnk3s4kb_MODIFIED.xcl>.
- The function using the strings must cast the pointer from RAM to FLASH type. This is because the pointer is actually pointing at the correct address in FLASH, but the compiler still believes it is a RAM pointer. For example:
void print_string(BYTE *string_temp)
- {
- BYTE flash *string;
- string = (BYTE flash *)(WORD)string_temp;
- ...
- }
"string_temp" is an invalid RAM pointer, but the FLASH pointer "string" can now be used normally instead.
- In some cases, pre-defined strings are preferred if a string is used multiple times. But now the problem is vice versa: The function is expecting a RAM pointer, but the pointer is in this case actually FLASH. So we have to cast the pointer to RAM to be able to compile the code:
BYTE flash *string_example = "Hello World!"; print_string( (BYTE *)(WORD)string_example );
Code description
General program structure
After initialisation, the program enters an infinite loop in which all processes are executed. Some processes are executed every 10ms, while others run continuously.
To generate the 10ms intervals, TIMER0 interrupt is used. It increments a counter by 1 every 10ms. The main loop checks this counter, and executes the required processes if it is greater than 0. Also, the counter is decremented by 1.
The process states and timers are kept within the separate processes, and no high-level FSM is used. Global status flags are held in a bit-struct register "status".
Keyboard scanning
| Located in file: | <main.c> |
| Entry function: | scan_matrix_keyboard() |
Hardware
The station keyboard is an 8x4 matrix connected to PB1-PD3 (outputs) and PD4-PD7 (inputs).
Debounce routine
For each of the 32 keys there is a debounce register of 8 bits:
| Key status: | 1 bit |
| Key counter up: | 3 bits |
| Key counter down: | 4 bits |
The keyboard scanning process is executed by 10ms intervals. For a keypress to be accepted, the key must be held for a specified amount of 10ms counts, counted by the up-counter. The key code is then sent to the AlphaCom digit sending process. Similarly, a key release also requires the key to be released for some time, counted by the down-counter. The key code 0x80 is then sent, telling the digit process to stop sending.
Key codes
The 32 keys are mapped this way:
| Position | Key name: | Key code: (1) | Comment |
|---|---|---|---|
| COL1, ROW1 | KEY_1 | 0x01 | |
| COL1, ROW2 | KEY_2 | 0x02 | |
| COL1, ROW3 | KEY_3 | 0x03 | |
| COL1, ROW4 | KEY_MENU | 0x2a | DAK 20 |
| COL2, ROW1 | KEY_4 | 0x04 | |
| COL2, ROW2 | KEY_5 | 0x05 | |
| COL2, ROW3 | KEY_6 | 0x06 | |
| COL2, ROW4 | KEY_UPARROW | 0x2b | DAK 21 |
| COL3, ROW1 | KEY_7 | 0x07 | |
| COL3, ROW2 | KEY_8 | 0x08 | |
| COL3, ROW3 | KEY_9 | 0x09 | |
| COL3, ROW4 | KEY_DOWNARROW | 0x2c | DAK 22 |
| COL4, ROW1 | KEY_M | 0x35 | (2) |
| COL4, ROW2 | KEY_0 | 0x0a | |
| COL4, ROW3 | KEY_C | 0x5f | (3) |
| COL4, ROW4 | KEY_NAME | 0x2d | DAK 23 |
| COL5, ROW1 | KEY_DAK1 | Key codes depend on which DAK page is currently displayed. (4) | |
| COL5, ROW2 | KEY_DAK2 | " | |
| COL5, ROW3 | KEY_DAK3 | " | |
| COL5, ROW4 | KEY_DAK4 | " | |
| COL6, ROW1 | KEY_DAK5 | " | |
| COL6, ROW2 | KEY_DAK6 | " | |
| COL6, ROW3 | KEY_DAK7 | " | |
| COL6, ROW4 | KEY_DAK8 | " | |
| COL7, ROW1 | KEY_DAK9 | " | |
| COL7, ROW2 | KEY_DAK10 | " | |
| COL7, ROW3 | |||
| COL7, ROW4 | KEY_PRIVACY | (No code) | Other signalling. |
| COL8, ROW1 | |||
| COL8, ROW2 | |||
| COL8, ROW3 | |||
| COL8, ROW4 |
(1): For the complete list of key codes and their signalling, see chapter [4.3 AlphaCom digit sending].
(2): The M-key code is not sent upon keypress. Instead, the global status "status.mkey" is set. Handset M-key will also set "status.mkey" when pressed.
(3): The C-key code is not sent upon keypress. Instead, the global status "status.ckey" is set.
(4): The DAK key codes depend on which DAK page is currently displayed on the upper LCD. There are 50 DAK key codes available, and by adding a prefix code (0x74) this amount is doubled. The key codes are according to the CRM IV station standard, which defines the following table:
| DAK page displayed: | DAK keys: | Key codes: | Comment |
|---|---|---|---|
| 0 | D0-D9 | 0x20-0x29 | |
| 1 | D10-D19 | 0x0a-0x13 | |
| 2 | D20-D29 | 0x2a-0x33 | Menu keys |
| 3 | D30-D39 | 0x60-0x69 | |
| 4 | D40-D49 | 0x6a-0x73 | |
| 5 | D50-D59 | (0x74+) 0x20-0x29 | |
| 6 | D60-D69 | (0x74+) 0x0a-0x13 | |
| 7 | D70-D79 | (0x74+) 0x2a-0x33 | |
| 8 | D80-D89 | (0x74+) 0x60-0x69 | |
| 9 | D90-D99 | (0x74+) 0x6a-0x73 |
Other input pins
There are some extra inputs that are also scanned by the keyboard process:
- PE2: C-D loop sense (conversation/station LED)
- PC1: Handset OFF
- PC0: Handset M-key
AlphaCom digit sending
| Located in file: | <main.c> |
| Entry functions: <br\> | digit_process()<br\>put_digit_in_buffer() |
Digit transmission is processed by the function "digit_process()". The digits are sent by two signals:
- Tone frequencies
- o Sent on C-D wires (microphone). Polarity is inverted first.
- o Frequency range: 400Hz - 4000Hz.
- Current-signals
- o Sent on A-B wires (speaker).
- o Signal levels: (Note: The station itself consumes 10mA (1) at all times, which is included in the values below)
Handset OFF: 10mA (1) Handset ON: 13mA M-key: 24mA C-key: 50mA
(1): Due to high power consumption, the station is currently set to consume 13mA at all times. This is equal to "Handset ON" signal (13mA), and the "Handset OFF" signal (10mA) can never be signalled. This is configured in hardware, and does not affect the software.