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Arduino_OptaBluePrint

This library is intended to be used on Arduino OPTA (use Controller class) and Arduino OPTA DIGITAL (use Module class) expansion. A single Arduino OPTA can control several Arduino Digital module expansions. More different types of expansion are expected and this library is ready to add them.

HW

Arduino OPTA and Arduino OPTA DIGITAL shares an I2C bus and a sort of UART bus ( OPTA Tx is wired on all OPTA DIGITAL Rx).

Arduino OPTA has a PIN that goes toward expansions (other Arduino Digital), this PIN is the DETECT PIN. Please note that this pin can only be input due to HW implementation.

Each expansion (Arduino Digital) has 2 PIN connected on the expansion bus.

  • DETECT IN goes toward the OPTA controller
  • DETECT OUT goes toward other Arduino DIGITAL possibly connected

The Serial bus is used only to upgrade the FW on the expansions (they do not have a USB connector mounted). Basically the controller send an I2C message to expansion asking to go in bootloader mode, once the bootloader is active the Serial Line is used to download the new FW into the expansion. Then the controller tells the bootloader to reset the board and the upgrade is done.

I2C

Arduino OPTA is always the master of the I2C, while the other expansions as Arduino OPTA DIGITAL are always slave on the I2C.

ASSIGN ADDRESSES PROCESS

Purposes of the ASSIGN ADDRESSES PROCESS

Controller (OPTA) will be always placed on the leftmost position. One or more expansions (not necessarily of the same type) can be chained on the right of the controller.

+------------+     +-------------+     +-------------+     +-------------+
|            |     |             |     |             |     |             |
| Controller |<--->| Expansion 0 |<--->| Expansion 1 |<--->| Expansion 2 |  [...]
|            |     |             |     |             |     |             |
+------------+     +-------------+     +-------------+     +-------------+

At the end of the ASSIGN ADDRESSES PROCESS:

  1. All expansion must have always the same address (this because the controller sketch must continue to address the same device, if addresses were chosen randomly the controller logic will have to change depending on the assigned addresses)
  2. The expansion closest to Controller must have address 0xB, other expansions must have address that are increased of 1 going in the right direction (so in our case shown above:
    • Expansion 0 gets address 0x0B
    • Expansion 1 gets address 0x0C
    • Expansion 2 gets address 0x0D always).
  3. This process must not be depending on the order the devices are powered up (or reset, if you will). As soon as 1 device is wired and powered up all the ASSIGN ADDRESSES PROCESS is refreshed.

PIN usage

CONTROLLER DETECT PIN is always an INPUT: if HIGH there is not not need to assign addresses, if LOW there are Expansions without an assigned address. At the reset the controller always checks the DETECT pin if it LOW the Controller enter into the ASSIGN ADDRESSES MODE. The controller remains that mode until the DETECT pin goes HIGH.

At the reset each expansion calls the reset() function (called by begin()). The reset() function performs the following operation:

  • stops and de-initialize the I2C (this guarantee that expansion does not receive any message until the I2C is properly initialized again)
  • puts the DETECT IN pin to LOW (this signals the Expansion has not valid address)
  • puts the DETECT OUT pin LOW for OPTA_MODULE_DETECT_OUT_PIN_LOW ms (this signals other expansions that one expansion on the left has been reset)
  • puts the DETECT OUT pin as INPUT_PULLUP
  • remain in this state until the DETECT OUT becomes HIGH
  • as soon as the DETECT OUT becomes HIGH the I2C is initialized as slave with the default address (0x0A)

After reset (see updatePinStatus()) the pin usage on Expansion depends upon the address acquisition. If address has NOT been acquired the DETECT IN (toward Controller) is kept LOW. If address has been acquired:

  • the DETECT IN (toward Controller) is briefly configured as INPUT to check if the DETECT OUT of the expansion on left is LOW (the expansion on the left is resetting its own address)
  • the DETECT OUT is checked, if it becomes LOW this mean that an expansion has been inserted on the right The previous 2 conditions and the reception of the RESET message from the controller trigger again the function reset() so that the complete ASSIGN ADDRESS PROCESS is performed when one of this event is detected by one of the Expansion that already have an address.

I2C assing process

At start-up the controller send to the address 0x0B (this is guarantee to be always the first device on the right of the controller when addresses have been assigned) the RESET message: this is done to deal with the case that expansions have already addresses assigned and the controller is somehow reset or switched off and on again. This message will trigger the first expansion to call the reset() function (see above).

After OPTA_CONTROLLER_SETUP_INIT_DELAY if the DETEC PIN is LOW the Controller starts the first phase of the assign addresses procedure. During this phase the controller send:

  1. a set address message to default address (0x0A); the address is set to OPTA_CONTROLLER_FIRST_AVAILABLE_ADDRESS + OPTA_CONTROLLER_MAX_EXPANSION_NUM (0x0B + 0x0A) at first and then increased of one after each expansion has successfully set the address. All expansions, due to the "reset" procedure, have the I2C in a de-initialized state, except the rightmost one (because its DETECT OUT is HIGH): for this reason only the rightmost expansion receives the message and configure its address. Once the Expansion gets the address it put its DETECT IN pin HIGH to leave the other expansions on the left the chance to get their own address.
  2. a get address and type message is sent to the last address set: this is done to ensure that the expansion has correctly obtained the address. With this message also a code that represent which expansion is attached is sent to the controller so that it can know what expansion types is dealing with (this make sense only if other expansion types than OPTA DIGITAL will be available - but this is expected). If an answer is received the address to be sent is increased by one and the controller start over: does the DETECT PIN is LOW? if yes go to the point 1 otherwise continue with normal operations.

At the end of this phase:

  • all expansion have a temporary address
  • the controller knows the number of expansions and their types (and their temporary addresses)

However the addresses are not always the same: the first device on the right of the controller will get an address that depends on the number of expansions chained together.

The Controller detects the end of this first phase by the fact that the DETECT PIN has a transition LOW -> HIGH. When the Controller detects that it starts the second phase. Starting from the device with the higher address (which is the one on right of the controller), the controller reassign the addresses starting from 0x0B (OPTA_CONTROLLER_FIRST_AVAILABLE_ADDRESS). At the end of this phase all the expansions have always the same address that only depends upon the position in the expansion chain: from left to right 0x0B, 0x0C, 0x0D and so on...

During this second phase the Controller also creates the data structures used to deal with all the expansions. In particular:

  • num_of_exp --> the number of expansions detected

  • exp_add[] --> is an array that holds the addresses assigned to each expansion (index 0 is the leftmost expansion index [num_of_exp - 1] is the rightmost expansion)

  • exp_type[] --> is an array that holds the type of each expansion (index 0 is the leftmost expansion index [num_of_exp - 1] is the rightmost expansion)

  • exp_index[] --> is an array holds the index in array of data structures that holds all the information related to a certain type of expansion To explain this lets have for example the following situation:

    1. expansion type A (index 0)
    2. expansion type B (index 1)
    3. expansion type A (index 2)
    4. expansion type B (index 3) So we have 2 expansion of type A and 2 expansion of type B. The controller then will create 2 arrays of different structures (classes) to hold the information of 2 different types of expansion. At the present only Digital expansions are defined and the correspondent array is kept in the variables:
    - uint8_t opta_digital_num;
    - OptaDigitalData *opta_digitals
    

    Suppose that OPTA digital is type A and that there is a different kind of expansion (maybe an OPTA ANALOG) which is the type B. Then we will have

    opta_digital_num = 2;
    opta_analog_num = 2;
    opta_digitals is an array with 2 position
    opta_analogs is an array with 2 position
    

    in this situation

    • exp_index[0] is 0 to indicate that (being the device at index 0 of type A or DIGITAL, this is got from exp_type[0]) all the information related to this device will be hold the opta_digitals[0] array position.
    • exp_index[1] is 0 to indicate that (being the device at index 1 of type B or ANALOG, this is got from exp_type[1]) all the information related to this device will be hold the opta_analogs[0] array position.
    • exp_index[2] is 1 to indicate that (being the device at index 2 of type A or DIGITAL, this is got from exp_type[2]) all the information related to this device will be hold the opta_digitals[1] array position.
    • exp_index[3] is 1 to indicate that (being the device at index 3 of type B or ANALOG, this is got from exp_type[3]) all the information related to this device will be hold the opta_analogs[1] array position.

    Using this structure and given an index (the index is alway the physical position of the expansions in the chain from left to right starting from 0) the controller knows always which expansion is dealing with and how to retrive / write information to it.

    Say we want to know the status of a pin on expansion which has index 2. The controller goes in exp_type[2] and gets the type of the device (type A or DIGITAL in our example), then it goes to exp_index[2] and retrive the position

    1. With this it will retreive information from opta_digitals[1].

About classes

Module is the base class for Expansions. This class handles the assign addresses process and so it parse the related messages and handle the related Pin setting.

There are mainly 4 public functions in this class:

  1. begin() -> initialize HW stuff
  2. parse_rx() -> parse the messages related to assign addresses process
  3. update() -> just call updatePinStatus() which is a private function handling the pin setting related to assign addresses process
  4. end() -> does nothing

The OptaDigital is the class specific for the OptaDigital management. So it handles all the HW stuff specific for that HW: in particular analog conversion, digital input and digital output.

This class overrides the functions of the Module class, however the base class functions are called into the derived class versions. THIS IS IMPORTANT TO REMEMBER when new hw will be added: ALWAYS CALL the base version function of the Module class, since this functions deal with the stuff that all expansions are suppose to handle (such the assign addresses process).

In particular it is supposed that a base Module class will never be instantiated.

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