73S8014RT TERIDIAN [Teridian Semiconductor Corporation], 73S8014RT Datasheet - Page 16

73S8014RT

Manufacturer Part Number

73S8014RT

Description

Smart Card Interface

Manufacturer

TERIDIAN [Teridian Semiconductor Corporation]

Datasheet

1.73S8014RT.pdf (29 pages)

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3.2 System Controller Interface

Three digital inputs allow direct control of the card interface by the host.

The 73S8014RT is controlled as follows:

Card clock frequency can be controlled by 2 digital inputs:

Interrupt output to the host: As long as the card is not activated, the OFF pin informs the host about the card

presence only (Low = No card in the reader). When CMDVCC% or CMDVCC# is asserted low (Card activation

sequence requested from the host), low level on OFF means a fault has been detected (e.g. card removal during

card session, voltage fault, or over-current fault) that automatically initiates a deactivation sequence.

3.3 Power Supply and Voltage Supervision

The Teridian 73S8014RT smart card interface ICs incorporate an LDO voltage regulator. The voltage output is

controlled by both the CMDVCC% and CMDVCC# pins. This regulator is able to provide either 3V or 5V or 1.8V

card voltage from the power supply applied on the VPC pin. The voltage regulator can provide a current of at

least 65mA on VCC for both 3V and 5V that complies with EMV 4.0.

Digital circuitry is powered by the power supply applied on the VDD pin.

interface with the system controller. A card deactivation sequence is forced upon fault of any of this voltage

supervisor. One voltage supervisor constantly monitors the

sequencer at power-on, and to deactivate the card at power-off or upon fault. The voltage threshold of the

voltage supervisor is internally set by default to 2.26V nominal. However, it may be desirable, in some

applications, to modify this threshold value.

The method of adjusting the

supply and R1 from the VDDF_ADJ pin to ground (see application schematics). In order to set the new threshold

voltage, the equivalent voltage divider ratio must be determined. This ratio value will be designated Kx. Kx is

defined as R1/(R1+R3). Kx is calculated as:

Kx = (2.71 / V

To determine the values of R1 and R3, use the following formulas (the parallel resistance of R1 and R3 is

selected to be 24000 ohms)

R3 = 24000 / Kx

Taking the example above, where a V

Solving for R3 gives:

Solving for R1 gives:

Using standard 1 % resistor values gives R3 = 53.6KΩ and R1 = 43.2KΩ.

Pins CMDVCC% and/or CMDVCC#: When low, starts an activation sequence at the voltage specified in Table 9.

Pin RSTIN: controls the card RST signal (when enabled by the sequencer)

CLKDIV1 and CLKDIV2 define the division rate for the clock frequency, from the input clock frequency (crystal

or external clock)

Control Pins

CMDVCC%

Kx = (2.71 / 2.6) - 0.595 = 0.4473.

) - 0.595 where V

CMDVCC#

R1 = R3*(Kx / (1 – Kx))

R3 = 24000 / 0.4473 = 53654.

R1 = 58752 *(0.4473 / (1 – 0.4473)) = 43422.

fault voltage is to use a resistive network of R3 from the VDDF_ADJ pin to

is the desired new threshold voltage.

Voltage

1.8V

Table 9: V

fault threshold voltage of 2.6V is desired, solving for Kx gives:

Off

Must be asserted within 400ns of each other to generate 1.8V

Voltage Logic Table

voltage. It is used to initialize the ISO-7816-3

also defines the voltage range to

Notes

Rev. 1.0

73S8014RT TERIDIAN [Teridian Semiconductor Corporation], 73S8014RT Datasheet - Page 16

73S8014RT

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