COM20051 Datasheet, PDF(24/82 Page) List of Unclassifed Manufacturers – Integrated Microcontroller and ARCNET (ANSI 878.1) Interface

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COM20051 Datasheet, PDF (24/82 Pages) List of Unclassifed Manufacturers – Integrated Microcontroller and ARCNET (ANSI 878.1) Interface

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ARCNET CORE FUNCTIONAL DESCRIPTION

MICROSEQUENCER

The ARCNET core contains an internal

microsequencer which performs all of the control

operations necessary to carry out the ARCNET

protocol. It consists of a clock generator, a 544 x

8 ROM, a program counter, two instruction

registers, an instruction decoder, a no-op

generator, jump logic, and reconfiguration logic.

The ARCNET core derives The Program Counter

Clock and Instruction Execution Clock from the

SYSTEM CLOCK. If the system clock is 40 MHz

the Program Counter Clock runs at 10 MHz and

the Instruction Execution Clock runs at 5 MHz. If

the System Clock is 20 MHz the above clocks

run at 5 MHz and 2.5 MHz respectively. The

microprogram is stored in the ROM and the

instructions are fetched and then placed into the

instruction registers. One register holds the op

code, while the other holds the immediate data.

Once the instruction is fetched, it is decoded by

the internal instruction decoder, at which point

the ARCNET core proceeds to execute the

instruction. When a no-op instruction is

encountered, the microsequencer enters a timed

loop and the program counter is temporarily

stopped until the loop is complete. When a jump

instruction is encountered, the program counter

is loaded with the jump address from the ROM.

The ARCNET core contains an internal

reconfiguration timer which interrupts the

microsequencer if it has timed out. At this point

the program counter is cleared and the

MYRECON bit of the Diagnostic Status Register

is set.

INTERNAL REGISTERS

The ARCNET core contains eight internal

registers. Tables 4 and 5 illustrate the ARCNET

core register map. Reserved locations should

not be accessed. All undefined bits are read as

undefined and must be written as logic "0".

Interrupt Mask Register (IMR) (Location

+00Hex)

The ARCNET core is capable of generating an

interrupt signal when certain status bits become

true. A write to the IMR specifies which status

bits will be enabled to generate an interrupt. The

bit positions in the IMR are in the same position

as their corresponding status bits in the Status

"1" in a particular position enables the

corresponding interrupt. The Status bits capable

of generating an interrupt include the Receiver

Inhibited bit, New Next ID bit, Excessive NAK bit,

Reconfiguration Timer bit, and Transmitter

Available bit. No other Status or Diagnostic

Status bits can generate an interrupt.

The five maskable status bits are ANDed with

their respective mask bits, and the results are

ORed to produce the interrupt signal. An RI

or TA interrupt is masked when the

corresponding mask bit is reset to logic "0", but

will reappear when the corresponding mask bit is

set to logic "1" again, unless the interrupt status

condition has been cleared by this time. A

RECON interrupt is cleared when the "Clear

Flags" command is issued. An EXCNAK

interrupt is cleared when the "POR Clear Flags"

command is issued. A New Next ID interrupt is

cleared by reading the New Next ID Register.

The Interrupt Mask Register defaults to the value

0000 0000 upon hardware reset only. Refer to

Table 3 on the following page.

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