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TDA8024 Datasheet, PDF (10/29 Pages) NXP Semiconductors – IC card interface
Philips Semiconductors
IC card interface
Product specification
TDA8024
8.3 Clock circuitry
The card clock signal (CLK) is derived from a clock signal
input to pin XTAL1 or from a crystal operating at up to
26 MHz connected between pins XTAL1 and XTAL2.
The clock frequency can be fXTAL, 1/2 × fXTAL, 1/4 × fXTAL
or 1/8 × fXTAL. Frequency selection is made via
inputs CLKDIV1 and CLKDIV2 (see Table 1).
Table 1 Clock frequency selection; note 1
CLKDIV1
0
CLKDIV2
0
fCLK
-f-X---T8---A---L-
0
1
f--X---T4---A---L-
1
1
f--X---T2---A---L-
1
0
fXTAL
Note
1. The status of pins CLKDIV1 and CLKDIV2 must not be
changed simultaneously; a delay of 10 ns minimum
between changes is needed; the minimum duration of
any state of CLK is eight periods of XTAL1.
The frequency change is synchronous, which means that
during transition no pulse is shorter than 45% of the
smallest period, and that the first and last clock pulses
about the instant of change have the correct width.
When changing the frequency dynamically, the change is
effective for only eight periods of XTAL1 after the
command.
The duty factor of fXTAL depends on the signal present at
pin XTAL1.
In order to reach a 45 to 55% duty factor on pin CLK, the
input signal on pin XTAL1 should have a duty factor of
48 to 52% and transition times of less than 5% of the input
signal period.
If a crystal is used, the duty factor on pin CLK may be
45 to 55% depending on the circuit layout and on the
crystal characteristics and frequency.
In other cases, the duty factor on pin CLK is guaranteed
between 45 and 55% of the clock period.
The crystal oscillator runs as soon as the IC is powered up.
If the crystal oscillator is used, or if the clock pulse on
pin XTAL1 is permanent, the clock pulse is applied to the
card as shown in the activation sequences shown in Figs 7
and 8.
If the signal applied to XTAL1 is controlled by the system
microcontroller, the clock pulse will be applied to the card
when it is sent by the system microcontroller (after
completion of the activation sequence).
8.4 I/O transceivers
The three data lines I/O, AUX1 and AUX2 are identical.
The idle state is realized by both I/O and I/OUC lines being
pulled HIGH via a 11 kΩ resistor (I/O to VCC and I/OUC to
VDD).
Pin I/O is referenced to VCC, and pin I/OUC to VDD, thus
allowing operation when VCC is not equal to VDD.
The first side of the transceiver to receive a falling edge
becomes the master. An anti-latch circuit disables the
detection of falling edges on the line of the other side,
which then becomes a slave.
After a time delay td(edge), an N transistor on the slave side
is turned on, thus transmitting the logic 0 present on the
master side.
When the master side returns to logic 1, a P transistor on
the slave side is turned on during the time delay tpu and
then both sides return to their idle states.
This active pull-up feature ensures fast LOW-to-HIGH
transitions; as shown in Fig.6, it is able to deliver more than
1 mA at an output voltage of up to 0.9VCC into an 80 pF
load. At the end of the active pull-up pulse, the output
voltage depends only on the internal pull-up resistor and
the load current.
The current to and from the card I/O lines is limited
internally to 15 mA and the maximum frequency on these
lines is 1 MHz.
2004 July 12
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