CP3BT10 Datasheet, PDF(138/210 Page) National Semiconductor (TI) – Reprogrammable Connectivity Processor with Bluetooth and USB Interfaces

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CP3BT10 Datasheet, PDF (138/210 Pages) National Semiconductor (TI) – Reprogrammable Connectivity Processor with Bluetooth and USB Interfaces

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21.3.7 ACB Own Address Register 1 (ACBADDR1)

The ACBADDR1 register is a byte-wide, read/write register

that holds the moduleâs first ACCESS.bus address. After re-

set, its value is undefined.

SAEN

ADDR

SAEN

The Own Address field holds the first 7-bit AC-

CESS.bus address of this device. When in

slave mode, the first 7 bits received after a

Start Condition are compared to this field (first

bit received to bit 6, and the last to bit 0). If the

address field matches the received data and

the SAEN bit is set, a match is detected.

The Slave Address Enable bit controls wheth-

er address matching is performed in slave

mode. When set, the SAEN bit indicates that

the ADDR field holds a valid address and en-

ables the match of ADDR to an incoming ad-

dress byte. When cleared, the ACB does not

check for an address match.

0 â Address matching disabled.

1 â Address matching enabled.

21.3.8 ACB Own Address Register 2 (ACBADDR2)

The ACBADDR2 register is a byte-wide, read/write register

that holds the moduleâs second ACCESS.bus address. After

reset, its value is undefined.

SAEN

ADDR

SAEN

The Own Address field holds the second 7-bit

ACCESS.bus address of this device. When in

slave mode, the first 7 bits received after a

Start Condition are compared to this field (first

bit received to bit 6, and the last to bit 0). If the

address field matches the received data and

the SAEN bit is set, a match is detected.

The Slave Address Enable bit controls wheth-

er address matching is performed in slave

mode. When set, the SAEN bit indicates that

the ADDR field holds a valid address and en-

ables the match of ADDR to an incoming ad-

dress byte. When cleared, the ACB does not

check for an address match.

0 â Address matching disabled.

1 â Address matching enabled.

21.4 USAGE HINTS

Â When the ACB module is disabled, the ACBCST.BB bit is

cleared.

After

enabling

the

ACB

(ACBCTL2.ENABLE = 1) in systems with more than one

master, the bus may be in the middle of a transaction with

another device, which is not reflected in the BB bit. There

is a need to allow the ACB to synchronize to the bus ac-

tivity status before issuing a request to become the bus

master, to prevent bus errors. Therefore, before issuing

a request to become the bus master for the first time,

software should check that there is no activity on the bus

by checking the BB bit after the bus allowed time-out pe-

riod.

Â When waking up from power down, before checking the

ACBCST.MATCH bit, test the ACBCST.BUSY bit to make

sure that the address transaction has finished.

Â The BB bit is intended to solve a deadlock in which two,

or more, devices detect a usage conflict on the bus and

both devices cease being bus masters at the same time.

In this situation, the BB bits of both devices are active

(because each deduces that there is another master cur-

rently performing a transaction, while in fact no device is

executing a transaction), and the bus would stay locked

until some device sends a ACBCTL1.STOP condition.

The ACBCST.BB bit allows software to monitor bus us-

age, so it can avoid sending a STOP signal in the middle

of the transaction of some other device on the bus. This

bit detects whether the bus remains unused over a cer-

tain period, while the BB bit is set.

Â In some cases, the bus may get stuck with the SCL or

SDA lines active. A possible cause is an erroneous Start

or Stop Condition that occurs in the middle of a slave re-

ceive session. When the SCL signal is stuck active, there

is nothing that can be done, and it is the responsibility of

the module that holds the bus to release it. When the

SDA signal is stuck active, the ACB module enables the

release of the bus by using the following sequence. Note

that in normal cases, the SCL signal may be toggled only

by the bus master. This protocol is a recovery scheme

which is an exception that should be used only in the

case when there is no other master on the bus. The re-

covery scheme is as follows:

1. Disable and re-enable the module to set it into the not

addressed slave mode.

2. Set the ACBCTL1.START bit to make an attempt to

issue a Start Condition.

3. Check if the SDA signal is active (low) by reading

ACBCST.TSDA bit. If it is active, issue a single SCL

cycle by writing 1 to ACBCST.TGSCL bit. If the SDA

line is not active, continue from step 5.

4. Check if the ACBST.MASTER bit is set, which indi-

cates that the Start Condition was sent. If not, repeat

step 3 and 4 until the SDA signal is released.

5. Clear the BB bit. This enables the START bit to be ex-

ecuted. Continue according to âBus Idle Error Recov-

eryâ on page 133.

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