TDA8001 Datasheet, PDF(7/24 Page) NXP Semiconductors

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TDA8001 Datasheet, PDF (7/24 Pages) NXP Semiconductors – Smart card interface

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Philips Semiconductors

Smart card interface

Product speciï¬cation

TDA8001

FUNCTIONAL DESCRIPTION

Power supply

The circuit operates within a supply voltage range of

6.7 to 18 V. VDD and GND are the supply pins. All card

contacts remain inactive during power up or down.

POWER UP

The logic part is powered first and is in the reset condition

until VDD reaches Vth1. The sequencer is blocked until VDD

reaches Vth4 + Vhys4.

POWER DOWN

When VDD falls below Vth4, an automatic deactivation of

the contacts is performed.

Voltage supervisor

This block surveys the 5 V supply of the microcontroller

(VSUP) in order to deliver a defined reset pulse and to avoid

any transients on card contacts during power up or down

of VSUP. The voltage supervisor remains active even if VDD

is powered-down.

POWER ON

As long as VSUP is below Vth2 + Vhys2 the capacitor CDEL,

connected to pin DELAY, will be discharged. When VSUP

rises to the threshold level, CDEL will be recharged.

ALARM and ALARM remain active, and the sequencer is

blocked until the voltage on the DELAY line reaches Vth3.

POWER DOWN (see Fig.4)

If VSUP falls below Vth2, CDEL will be discharged, ALARM

and ALARM become active, and an automatic deactivation

of the contacts is performed.

Clock circuitry (see Fig.5)

The clock signal (CLK) can be applied to the card in two

different methods:

1. Generation by a crystal oscillator: the crystal, or the

ceramic resonator (4 to 16 MHz) is connected to the

XTAL pin.

2. Use of a signal frequency (up to 20 MHz), already

present in the system and connected to the XTAL pin

via a 10 nF capacitor (see Fig.14). In both cases the

frequency is first divided-by-two.

If CMD7 (respectively CMD3.5) is LOW, the clock signal

(its frequency again divided by two) is enabled and

buffered before being fed to the CLK pin.

CMD3.5 and internal ENRST are sampled in order to give

the first clock pulse the correct width, and to avoid false

pulses during frequency change.

The CLKOUT2 pins may be used to clock a

microcontroller or an other TDA8001. The signal 1â2 fxtal is

available when the circuit is powered up.

State diagram

Once activated, the circuit has six possible modes of

operation:

â¢ Idle

â¢ Activation

â¢ Read

â¢ Write

â¢ Deactivation

â¢ Fault.

Figure 6 shows the way these modes are accessible.

IDLE MODE

After reset, the circuit enters the IDLE state. A minimum

number of circuits are active while waiting for the

microcontroller to start a session.

â¢ All card contacts are inactive

â¢ I/O(ÂµC) is high impedance

â¢ Voltage generators are stopped

â¢ Oscillator or XTAL input is running, delivering CLKOUT2

â¢ Voltage supervisors are active.

The DETECT line is HIGH if a card is present (PRES and

PRES active) and LOW if a card is not present. The OFF

line is HIGH if no hardware problem is detected.

ACTIVATION SEQUENCE

From the IDLE mode, the circuit enters the ACTIVATION

mode when the microcontroller sets the CMDVCC line

(active LOW). The I/O(ÂµC) signal must not be LOW.

The internal circuitry is activated, the internal clock starts

and the sequence according to ISO7816 is performed:

â¢ VCC rises from 0 to 5 V

â¢ VPP rises from 0 to 5 V and I/O is enabled

â¢ CLK and RST are enabled.

The time interval between steps 1 and 2 is 16 Âµs, and

64 Âµs between steps 2 and 3 (see Fig.7).

1996 Dec 12

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