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| Final Electrical Specifications LTC1755 Smart Card Interface October 1999 FEATURES s s s s s s s s s s s s DESCRIPTION The LTC(R)1755 universal Smart Card interface is fully compliant with ISO 7816-3 and EMV specifications. It provides the smallest and simplest interface circuit between a host microcontroller and general purpose Smart Cards. An internal charge pump DC/DC converter delivers regulated 3V or 5V to the Smart Card, while on-chip level shifters allow connection to a low voltage controller. All Smart Card contacts are rated for 10kV ESD, eliminating the need for external ESD protection devices. Input voltage may range from 2.7V to 6.0V, allowing direct connection to a battery. Automatic DC/DC converter soft start mitigates start-up problems that may result when the input power is provided by another regulator. Multiple LTC1755 devices may be paralleled and connected to a single controller for multicard applications. Battery life is maximized by 60A operating current and 1A shutdown current. The 24-pin SSOP package minimizes PCB area for compact portable systems. , LTC and LT are registered trademarks of Linear Technology Corporation. s Fully ISO 7816-3 and EMV Compliant (Including Auxiliary I/O Pins) Buck-Boost Charge Pump Generates 3V or 5V 2.7V to 6.0V Input Voltage Range Very Low Operating Current: 60A > 10kV ESD on All Smart Card Pins Dynamic Pull-Ups Deliver Fast Signal Rise Times Soft Start Limits Inrush Current at Turn On 3V 5V Signal Level Translators Shutdown Current: < 1A Short-Circuit and Overtemperature Protected Alarm Output Indicates Fault Condition Multiple Devices May Be Paralleled for Multicard Applications Available in 24-Pin SSOP Package APPLICATIONS s s s s s Handheld Payment Terminals Pay Telephones ATMs Key Chain Readers Smart Card Readers TYPICAL APPLICATION SMART CARD PRESENT SWITCH 1 2 3 4 C3 10F GND VCC AUX1 SMART CARD AUX2 I/O RST CLK C2 10F 5 6 7 8 9 10 11 12 3.3V PRES PWR CS NC/NO GND 5V/3V CARD ALARM READY DVCC C- C+ AUX1IN AUX2IN DATA RIN CIN 24 23 22 21 20 19 18 17 16 15 14 13 1755 TA01 VIN LTC1755 VCC AUX1 AUX2 I/O RST CLK Information furnished by Linear Technology Corporation is believed to be accurate and reliable. However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights. U U U C1 0.68F CONTROLLER 1 LTC1755 ABSOLUTE MAXIMUM RATINGS (Note 1) PACKAGE/ORDER I FOR ATIO TOP VIEW PRES PWR CS NC/NO GND VIN VCC AUX1 AUX2 1 2 3 4 5 6 7 8 9 24 5V/3V 23 CARD 22 ALARM 21 READY 20 DVCC 19 C - 18 C + 17 AUX1IN 16 AUX2IN 15 DATA 14 RIN 13 CIN VIN to GND ............................................... - 0.3V to 6.5V DVCC, VCC to GND .................................... - 0.3V to 5.5V Digital Inputs to GND ................ - 0.3V to (DVCC + 0.3V) CLK, RST, I/O, AUX1, AUX2 to GND .............................. - 0.3V to VCC + 0.3V VCC Short-Circuit Duration ............................... Indefinite Operating Temperature Range (Note 2) .. - 40C to 85C Storage Temperature Range ................ - 65C to 150C Lead Temperature (Soldering, 10 sec)................. 300C ORDER PART NUMBER LTC1755EGN I/O 10 RST 11 CLK 12 GN PACKAGE 24-LEAD NARROW PLASTIC SSOP TJMAX = 125C, JA = 150C/W Consult factory for Industrial and Military grade parts. The q denotes specifications which apply over the full specified temperature range, otherwise specificatons are at TA = 25C. VIN = 2.7V to 6V, DVCC = 2V to 5.5V, unless otherwise noted. PARAMETER Power Supply VIN Operating Voltage DVCC Operating Voltage IVIN Operating Current IDVCC Operating Current IVIN Shutdown Current ACTIVE State, IVCC = 0 ACTIVE State, DVCC = 3V IDLE State, DVCC = 0V, VIN 3.6V IDLE State, DVCC = 0V, 3.6V < VIN 6V IDLE State, DVCC = 5.5V, VIN 6V 5V/3V = DVCC 5V/3V = 0V 5V/3V = 0V 5V/3V = DVCC 5V/3V = 0V 5V/3V = DVCC VCC Turn-On Time VCC Discharge Time to 0.4V High Input Voltage Threshold (VIH) Low Input Voltage Threshold (VIL) High Level Output Voltage (VOH) Low Level Output Voltage (VOL) Output Rise/Fall Time Input Current (IIH/IIL) Source Current = 20A Sink Current = - 500A (Note 3) Loaded with 30pF CS = DVCC COUT = 10F IVCC = 0mA, VCC = 5V, COUT = 10F 3V VIN 6.0V 3V VIN 6.0V 2.7V VIN 6.0V 2.7V VIN 6.0V q q q q q q q q q q q q q q q ELECTRICAL CHARACTERISTICS CONDITIONS MIN 2.7 2.0 TYP MAX 6 5.5 UNITS V V A A A A A V V mA mA mA mA 50 10 100 20 1 10 20 VCC Output Voltage IVCC Output Current 4.75 2.80 55 65 55 40 5.00 3.00 5.25 3.20 2.7 100 DVCC - 0.6 0.5 * DVCC 0.5 * DVCC 0.7 * DVCC 12 250 Controller Inputs/Outputs DATA, AUX1IN, AUX2IN, DVCC = 3V q q q q q q 0.3 0.3 0.5 -1 1 2 U ms s V V V V s A W U U WW W LTC1755 The q denotes specifications which apply over the full specified temperature range, otherwise specificatons are at TA = 25C. VIN = 2.7V to 6V, DVCC = 2V to 5.5V, unless otherwise noted. PARAMETER RIN, CIN, PWR, CS, 5V/3V, NC/NO High Input Voltage Threshold (VIH) Low Input Voltage Threshold (VIL) Input Current (IIH/IIL) READY, ALARM, CARD Pull-Up Current (IOH) Low Level Output Voltage (VOL) High Input Voltage Threshold (VIH) Low Input Voltage Threshold (VIL) High Level Output Voltage (VOH) Low Level Output Voltage (VOL) Rise/ Fall Time Short-Circuit Current CLK High Level Output Voltage (VOH) Low Level Output Voltage (VOL) CLK Rise/Fall Time CLK Frequency RST High Level Output Voltage (VOH) Low Level Output Voltage (VOL) RST Rise/Fall Time PRES High Input Voltage Threshold (VIH) Low Input Voltage Threshold (VIL) PRES Pull-Up Current PRES Debounce Time Proportional to the 0.68F Charge Pump Capacitor q q q q q q q q ELECTRICAL CHARACTERISTICS CONDITIONS MIN TYP MAX UNITS V V A nA 0.7 * DVCC 0.5 * DVCC 0.5 * DVCC 0.2 * DVCC -1 250 0.3 0.6 * VCC 0.8 * VCC 0.3 0.5 3.5 VCC - 0.5 0.3 16 5 0.8 * VCC 0.3 0.5 0.7 * DVCC 0.5 * DVCC 0.5 * DVCC 0.2 * DVCC 0.5 40 1 80 5 0.5 * VCC 0.5 * VCC 0.8 1 Sink Current = - 20A IIH(MAX) = 20A IIL(MAX) = 1mA Source Current = 20A DATA, AUX1IN, AUX2IN = DVCC Sink Current = - 1mA DATA, AUX1IN, AUX2IN = 0V (Note 3) Loaded with 30pF Shorted to VCC Source Current = 100A Sink Current = - 200A CLK Loaded with 30pF CLK Loaded with 30pF Source Current = 200A Sink Current = - 200A Loaded with 30pF q V V V V V s mA V V ns MHz V V s V V A ms Smart Card Inputs/Outputs I/O, AUX1, AUX2, VCC = 3V or 5V q q q q q q q q q q q q q Note 1: Absolute Maximum Ratings are those values beyond which the life of a device may be impaired. Note 2: The LTC1755 is guaranteed to meet performance specifications from 0C to 70C. Specifications over the - 40C to 85C operating temperature range are assured by design, characterization and correlation with statistical process controls. Note 3: The DATA, AUX1IN, AUX2IN, AUX1, AUX2 and I/O pull-down drivers must sink up to 250A sourced by the internal current sources. 3 LTC1755 PIN FUNCTIONS PRES (Pin 1): (Input) Connects to the Smart Card acceptor's PRESENT indicator switch to detect if a card is inserted. This pin has a pull-up current source so that a grounded switch can be detected with no external components. The pull-up current source is nonlinear, delivering higher current when the PRES pin is above 1V but very little current below 1V. This helps resist false card indications due to leakage current. The activation state of the PRES pin can be set by the NC/NO pin so that both normally open (NO) and normally closed (NC) switches are easily recognized (see NC/NO pin description). DVCC sets the logic reference level for the PRES pin. PWR (Pin 2): (Input) A low on the PWR pin places the LTC1755 in the ACTIVE state enabling the charge pump. The READY pin indicates when the card supply voltage (VCC) has reached its final value and communication with the Smart Card is possible. The reset and clock channels are enabled after READY goes low. The three I/O channels are also enabled only after READY goes low, however they may be disabled separately via the CS pin. The falling edge of PWR latches the state of the 5V/3V pin. After PWR is low, changes on the 5V/3V pin are ignored. CS (Pin 3): (Input) The CS pin enables the three bidirectional I/O channels of the LTC1755. When the I/O channels are disabled the Smart Card pins (I/O, AUX1, AUX2) are forced to logic one and the controller pins (DATA, AUX2IN, AUX1IN) are high impedance. CS can be brought low along with PWR when the device is first enabled, however communication with the Smart Card is inhibited until VCC reaches its final value as indicated by a low on the READY pin. DVCC sets the logic reference level for the CS pin. NC/NO (Pin 4): (Input) This pin controls the activation level of the PRES pin. When it is high (DVCC) the PRES pin is active high. When it is low (GND) the PRES pin is active low. In either case the presence of a Smart Card is indicated by a low on the CARD output. When a ground side normally open (NO) switch is used the NC/NO pin should be grounded. When a ground side normally closed (NC) switch is used the NC/NO pin should be connected to DVCC. Note: If a normally closed switch is used, a small current (several microamperes) will flow through the switch whenever a Smart Card is not present. For ultralow power consumption in shutdown, a normally open switch is optimum. DVCC sets the logic reference level for the NC/NO pin. GND (Pin 5): Ground Reference for the IC. This pin should be connected to a low impedance ground plane. Bypass capacitors for VIN and VCC should be in close proximity to the GND pin. VIN (Pin 6): Supply Voltage for the Charge Pump. May be between 2.7V and 6V. A 10F low ESR ceramic bypass capacitor is required on this pin for optimum performance. VCC (Pin 7): Regulated Smart Card Supply Voltage. This pin should be connected to the Smart Card VCC contact. The 5V/3V pin determines the VCC output voltage. The VCC pin is protected against short circuits by comparing the actual output voltage with an internal reference voltage. If VCC is below its correct level (for as little as 5s) the LTC1755 switches to the Alarm state (see the State Diagram). The VCC pin requires a 10F charge storage capacitor to ground. For optimum performance a low ESR ceramic capacitor should be used. During the Idle and Alarm states the VCC pin is rapidly discharged to ground to comply with the deactivation requirements of the EMV and ISO-7816 specifications. AUX1 (Pin 8): (Input/Output) Smart Card Side Auxiliary I/O Pin. This pin is used for auxiliary bidirectional data transfer between the microcontroller and the Smart Card. It has the same characteristics as the I/O pin. AUX2 (Pin 9): (Input/Output) Smart Card Side Auxiliary I/O Pin. This pin is used for auxiliary bidirectional data transfer between the microcontroller and the Smart Card. It has the same characteristics as the I/O pin. I/O (Pin 10): (Input/Output) Smart Card Side Data I/O Pin. This pin is used for bidirectional data transfer between the microcontroller and the Smart Card. It should be connected to the Smart Card I/O contact. The Smart Card I/O pin must be able to sink up to 250A when driving the I/O pin low 4 U U U LTC1755 PIN FUNCTIONS due to the pull-up current source. The I/O pin becomes a low impedance to ground during the Idle state. It does not become active until READY goes low indicating that VCC is stable. Once READY is low the I/O pin is protected against short circuits to VCC by current limiting to 5mA maximum. The DATA-I/O channel is bidirectional for half-duplex transmissions. Its idle state is H-H. Once an L is detected on one side of the channel the direction of transmission is established. Specifically, the side which received an L first is now the input, and the opposite side is the output. Transmission from the output side back to the input side is inhibited, thereby preventing a latch condition. Once the input side releases its L, both sides return to H, and the channel is now ready for a new L to be transmitted in either direction. If an L is forced externally on the output side, and it persists until after the L on the input side is released, this illegal input will not be transmitted to the input side because the transmission direction will not have changed. The direction of transmission can only be established from the idle (H-H) state and is determined by the first receipt of an L on either side. RST (Pin 11): (Output) Level-Shifted Reset Output Pin. This pin should be connected to the Smart Card RST contact. The RST pin becomes a low impedance to ground during the Idle state (see the State Diagram). The reset channel does not become active until the READY signal goes low indicating that VCC is stable. Short-circuit protection is provided on the RST pin by comparing RST with RIN. If these signals differ for several microseconds then the LTC1755 switches to the Alarm state. This fault checking is only performed after the VCC pin has reached its final value (as indicated by the READY pin). CLK (Pin 12): (Output) Level-Shifted Clock Output Pin. This pin should be connected to the Smart Card CLK contact. The CLK pin becomes a low impedance to ground during the Idle state (see the State Diagram). The clock channel does not become active until the READY signal goes low indicating that VCC is stable. Short-circuit protection is provided on the CLK pin by comparing CLK with CIN. If these signals differ for several microseconds then the LTC1755 switches to the Alarm state. This fault checking is only performed after the VCC pin has reached its final value (as indicated by the READY pin). The clock channel is optimized for signal integrity in order to meet the stringent duty cycle requirements of the EMV specification. Therefore, to reduce power in low power applications, clock stop mode is recommended when data is not being exchanged. CIN (Pin 13): (Input) Clock Input Pin from the Microcontroller. During the Active state this signal appears on the CLK pin after being level-shifted and buffered. DVCC sets the logic reference level for the CIN pin. RIN (Pin 14): (Input) Reset Input Pin from the Microcontroller. During the Active state this signal appears on the RST pin after being level-shifted and buffered. DVCC sets the logic reference level for the RIN pin. DATA (Pin 15): (Input/Output) Microcontroller Side Data I/O Pin. This pin is used for bidirectional data transfer between the microcontroller and the Smart Card. The microcontroller data pin must be open drain and must be able to sink up to 250A when driving the DATA pin low due to the pull-up current source. The DATA pin becomes high impedance during the Idle state or when CS is high (see the State Diagram). It does not become active until the READY signal goes low indicating that VCC is stable. AUX2IN (Pin 16): (Input/Output) Microcontroller Side Auxiliary I/O pin. This pin is used for bidirectional auxiliary data transfer between the microcontroller and the Smart Card. It has the same characteristics as the DATA pin. AUX1IN (Pin 17): (Input/Output) Microcontroller Side Auxiliary I/O Pin. This pin is used for bidirectional auxiliary data transfer between the microcontroller and the Smart Card. It has the same characteristics as the DATA pin. C +, C - (Pins 18, 19): Charge Pump Flying Capacitor Terminals. Optimum values for the flying capacitor range from 0.68F to 1F. Best performance is achieved with a low ESR X7R ceramic capacitor. U U U 5 LTC1755 PIN FUNCTIONS DVCC (Pin 20): Supply Voltage for the Microcontroller Side Digital Input and Input/Output Pins (Typically 3V). If the charge pump input pin (VIN) is powered from the same source as the microcontroller, then DVCC should be connected directly to VIN. In this case only one (10F) input bypass capacitor is needed for the LTC1755. If the DVCC pin is powered separately then it should be bypassed separately with a 0.1F capacitor. The DVCC pin may be between 2V and 5.5V. The DVCC pin is monitored for adequate voltage. If DVCC drops below approximately 1.5V the LTC1755 automatically enters the Idle state. READY (Pin 21): (Output) Readiness Indicator of the Smart Card Supply Voltage (VCC). When the LTC1755 is placed in the Active state the soft start feature slowly ramps the VCC voltage. A low on the READY pin indicates that VCC has reached its final value. The READY pin is configured as an open-drain pull-down with a weak pull-up current source. This permits wiredOR connections of multiple LTC1755s to a single microcontroller. ALARM (Pin 22): (Output) A low on this pin indicates that a fault has occurred and that the LTC1755 is in the Alarm state (see the State Diagram). Possible faults include VCC underrange for at least 5s, overtemperature shutdown, CLK or RST invalid output levels, and card removal during the Active state. CLK or RST invalid and overtemperature faults are detected only after VCC has reached its final value (as indicated by the READY pin). VCC underrange and card removal during Active faults are detected at any time during the Active period (i.e., once PWR = 0V). The ALARM pin is configured as an open-drain pull-down with a weak pull-up current source. This permits wiredOR connections of multiple LTC1755s to a single microcontroller. CARD (Pin 23): (Output) Level-Shifted and Debounced PRES Signal from the Smart Card Acceptor Switch. When a valid card indication appears, this pin communicates the presence of the Smart Card to the microcontroller. The CARD pin has an open-drain active pull-down with a weak pull-up current source for logic-OR connections. The debounce circuit ensures that a card has been present for a continuous period of at least 40ms before asserting CARD low. The CARD pin returns high within 50s of card removal. The PRES pin, in conjunction with the NC/NO pin, determines if a card is present. 5V/3V (Pin 24): (Input) Controls the output voltage (VCC) of the DC/DC converter during the Active state. A valid high sets VCC to 5V. A valid low sets VCC to 3V. The 5V/3V pin is latched on the falling edge of the PWR pin. When PWR is low, changes on the 5V/3V pin are ignored. To change the voltage on VCC the LTC1755 must first be returned to the Idle state by bringing the PWR pin high. DVCC sets the logic reference level for the 5V/3V pin. 6 U U U LTC1755 BLOCK DIAGRA PRES 1 PWR 2 CS 3 NC/NO 4 GND 5 VIN 6 VCC 7 AUX1 8 AUX2 9 I/O 10 RST 11 CLK 12 *DYNAMIC PULL-UP CURRENT SOURCE W DVCC 24 5V/3V 23 CARD 22 ALARM 21 READY DC/DC CONVERTER AND CONTROL LOGIC 20 DVCC 19 C - 18 C + * * 17 AUX1IN * * 16 AUX2IN * * 15 DATA 14 RIN 13 CIN 1755 BD 7 LTC1755 APPLICATIONS INFORMATION 10kV ESD Protection All Smart Card pins (CLK, RST, I/O, AUX1, AUX2, VCC and GND) can withstand over 10kV of human body model ESD in situ. In order to ensure proper ESD protection, careful board layout is required. The GND pin should be tied directly to a ground plane. The VCC capacitor should be located very close to the VCC pin and tied immediately to the ground plane. Capacitor Selection The style and value of capacitors used with the LTC1755 determine several parameters such as output ripple voltage, charge pump strength, Smart Card switch debounce time and VCC discharge rate. Due to the switching nature of a capacitive charge pump, low equivalent series resistance (ESR) capacitors are recommended for the capacitors at VIN and VCC. Whenever the flying capacitor is switched to the VCC charge storage capacitor, considerable current flows. The product of this high current and the ESR of the output capacitor can generate substantial voltage spikes on the VCC output. These spikes may cause problems with the Smart Card or may interfere with the regulation loop of the LTC1755. Therefore, ceramic or tantalum capacitors are recommended rather than higher ESR aluminum capacitors. Between ceramic and tantalum, ceramic capacitors generally have the lowest ESR. Some manufacturers have developed low ESR tantalum capacitors but they can be expensive and may still have higher ESR than ceramic types. Thus, while they cannot be avoided, ESR spikes will typically be lowest when using ceramic capacitors. For ceramic capacitors there are several different materials available to choose from. The choice of ceramic material is generally based on factors such as available capacitance, case size, voltage rating, electrical performance and cost. For example, capacitors made of Y5V material have high packing density, which provides high capacitance for a given case size. However, Y5V capacitors tend to lose considerable capacitance over the - 40C to 85C temperature range. X7R ceramic capacitors are more stable over temperature but don't provide the high packing density. Therefore, large capacitance values are generally not available in X7R ceramic. The value and style of the flying capacitor are important not only for the charge pump but also because they provide the large debounce time for the Smart Card detection channel. A 0.68F X7R capacitor is a good choice for the flying capacitor because it provides fairly constant capacitance over temperature and its value is not prohibitively large. The charge storage capacitor on the VCC pin determines the ripple voltage magnitude and the discharge time of the Smart Card voltage. To minimize ripple, generally, a large value is needed. However, to meet the VCC discharge rate specification, the value should not exceed 20F. A 10F capacitor can be used but the ripple magnitude will be higher leading to worse apparent DC load regulation. Typically a 15F to 18F Y5V ceramic capacitor is the best choice for the VCC charge storage capacitor. For best performance, this capacitor should be connected as close as possible to the VCC and GND pins. Note that most of the electrostatic discharge (ESD) current on the six Smart Card pins is absorbed by this capacitor. The bypass capacitor at VIN is also important. Large dips on the input supply due to ESR may cause problems with the internal circuitry of the LTC1755. A good choice for the input bypass capacitor is a 10F Y5V style ceramic Dynamic Pull-Up Current Sources The current sources on the bidirectional pins (DATA, AUX2IN, AUX1IN, I/O, AUX2 and AUX1) are dynamically activated to achieve a fast rise time with a relatively small static current (Figure 1). Once a bidirectional pin is relinquished, a small start-up current begins to charge the node. An edge rate detector determines if the pin is released by comparing its slew rate with an internal VCC OR DVCC 8 U W U U + ISTART VREF - V t BIDIRECTIONAL PIN 1755 F01 Figure 1. Dynamic Pull-Up Current Sources LTC1755 APPLICATIONS INFORMATION reference value. If a valid transition is detected, a large pull-up current enhances the edge rate on the node. The higher slew rate corroborates the decision to charge the node thereby effecting a dynamic form of hysteresis. Once the node has reached the power supply voltage the internal comparator requires several hundred nanoseconds to reset. Pulling down on the pin before the reset delay expires will result in a momentary contention and a higher current flow. Therefore, the comparator delay sets the upper limit on the maximum data rate of the bidirectional channels to about 500kHz. Synchronous Card Applications For multicard synchronous applications the LTC1755 has separate control pins for the CLK and I/O lines. The PWR pin enables the charge pump as well as the CLK and RST channels while the CS pin enables only the bidirectional channels. In multicard applications the CS pin can be used to disable communication to one card while leaving its clock line running. With this option the same I/O pin can be used for multiple cards. For simpler applications the CS and PWR pins can be connected together to enable or disable the entire chip. Low Power Operation The LTC1755 is inherently a low power device. When there is no Smart Card present the supply current is less than 10A. If DVCC is 0V the current drops below 1A. When a Smart Card is present the LTC1755 operates with a quiescent current of only 60A, thus the majority of power is consumed by charge pump losses and the card itself. If the card can be made to consume less power during idle times a significant power savings will be achieved. Whenever possible Clock Stop Mode should be used (or alternatively a very low "idling" clock speed). Furthermore, in the Active state, the bidirectional pins should all be relinquished whenever possible since there is some static current flow when a bidirectional pin is pulled down. Overtemperature Fault Protection An overtemperature circuit disables the chip and activates the ALARM pin if the IC's junction temperature exceeds 150C. In the event of a fault, the LTC1755 automatically implements the built-in deactivation sequence. Self-Start Mode By connecting the CARD pin to the CS and PWR pins the LTC1755 can be made to start up automatically when a Smart Card is detected (Figure 2). In this mode, the READY pin becomes an interrupt signal indicating to the microcontroller that a Smart Card is present and that VCC, the charge pump voltage, is at its final value. The Smart Card remains powered as long as it is detected by the PRES pin. When the Smart Card is removed the LTC1755 will automatically be deactivated by the fault detection circuitry. U W U U CARD PWR CS 1755 F02 Figure 2. Self-Start Mode Deactivation Sequence For maximum flexibility the Smart Card can be deactivated either manually or automatically. In manual mode the deactivation is controlled by explicitly manipulating the LTC1755 input and control pins (DATA, AUX1IN, AUX2IN, RIN and CIN followed by PWR and CS). In automatic mode the PWR pin is used to perform the built-in deactivation sequence. Once PWR is brought high the built-in deactivation sequence occurs as follows: DEACTIVATION DIRECTIVE VCC RST RST = RIN CLK I/O AUX2 AUX1 CLK = CIN I/O = DATA 1755 F03 Figure 3. Deactivation Sequence 9 LTC1755 APPLICATIONS INFORMATION POWER OFF IDLE DEACTIVATION PWR = 0V PWR = DVCC ACTIVE PRES NC/NO PWR = DVCC NO FAULT ALARM DEACTIVATION FAULT > 5s or PRES NC/NO FAULT TIMEOUT 1755 F04 Figure 4. LTC1755 State Diagram State Definitions IDLE/DEACTIVATION VCC, RST, CLK, I/O AUX2, AUX1 = L READY, ALARM, DATA, AUX2IN, AUX1IN = Z CARD = PRES NC/NO Once the LTC1755 enters the Idle/Deactivation state the deactivation sequence begins. The deactivation sequence will continue until VCC is discharged to approximately 1V. An activation command (PWR = 0V) will only be acknowledged once this occurs. 10 U W U U ALARM/DEACTIVATION Same as Idle/Deactivation except: ALARM = L FAULT The only possible next state is Idle/Deactivation which is achieved by disabling the LTC1755 via the PWR pin (i.e., PWR = DVCC). The alarm indication can be cleared by rapidly cycling the PWR pin. However, a new activation cycle will not begin until VCC is or has dropped below approximately 1V. ACTIVE VCC = 3V or 5V (as determined by the 5V/3V pin) RST = RIN, CLK = CIN I/O, AUX2, AUX1, DATA, AUX2IN, AUX1IN = Ready for data (after READY becomes low) CARD = PRES NC/NO ALARM = H FAULT TIMEOUT Same as Active except: The duration of a fault is being measured. If the fault duration exceeds 5s then the Alarm/Deactivation state follows. If the fault duration is less than 5s, then the device is returned to the Active state. LTC1755 PACKAGE DESCRIPTION 0.007 - 0.0098 (0.178 - 0.249) 0.016 - 0.050 (0.406 - 1.270) * DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE ** DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE U Dimensions in inches (millimeters) unless otherwise noted. GN Package 24-Lead Plastic SSOP (Narrow 0.150) (LTC DWG # 05-08-1641) 0.337 - 0.344* (8.560 - 8.738) 24 23 22 21 20 19 18 17 16 15 1413 0.033 (0.838) REF 0.229 - 0.244 (5.817 - 6.198) 0.150 - 0.157** (3.810 - 3.988) 1 23 4 56 7 8 9 10 11 12 0.015 0.004 x 45 (0.38 0.10) 0 - 8 TYP 0.053 - 0.068 (1.351 - 1.727) 0.004 - 0.0098 (0.102 - 0.249) 0.008 - 0.012 (0.203 - 0.305) 0.0250 (0.635) BSC GN24 (SSOP) 1098 11 LTC1755 TYPICAL APPLICATION Paralleling Devices for Multicard Applications VIN SMART CARD PRESENT SWITCH C3 10F GND VCC AUX1 SMART CARD AUX2 I/O RST CLK SMART CARD PRESENT SWITCH C6 10F GND VCC AUX1 SMART CARD AUX2 I/O RST CLK RELATED PARTS PART NUMBER LTC1514/LTC1515 LTC1516 LTC1555/LTC1556 LTC1754-5 LTC1986 DESCRIPTION Micropower Step-Up/Step-Down Inductorless DC/DC Converters Micropower Regulated 5V Charge Pump SIM Power Supply and Level Translator 5V Charge Pump with Shutdown in SOT-23 3V/5V SIM Power Supply in SOT-23 COMMENTS Regulated Output Up to 50mA, VIN from 2V to 10V, SO-8 Package 5V/50mA Output from 2V to 5V Input, S0-8 Package Step-Up/Step-Down Charge Pump + SIM Level Translators, >10kV ESD VIN from 2.7V to 5.5V, 50mA Output with VIN 3V VIN from 2.6V to 4.4V, 3V/5V Output at 10mA 1755i LT/TP 1099 4K * PRINTED IN USA 12 Linear Technology Corporation 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408)432-1900 q FAX: (408) 434-0507 q www.linear-tech.com U 1 2 3 4 C2 10F 5 6 7 8 9 10 11 12 PRES PWR CS NC/NO GND 5V/3V CARD ALARM READY DVCC C- 24 23 22 21 20 19 C1 0.68F CONTROLLER VIN LTC1755 VCC AUX1 AUX2 I/O RST CLK 18 C+ AUX1IN AUX2IN DATA RIN CIN 17 16 15 14 13 1 2 3 4 C5 10F 5 6 7 8 9 10 11 12 PRES PWR CS NC/NO GND 5V/3V CARD ALARM READY DVCC C- C+ AUX1IN AUX2IN DATA RIN CIN 24 23 22 21 20 19 18 17 16 15 14 13 1755 TA02 VIN LTC1755 VCC AUX1 AUX2 I/O RST CLK C4 0.68F (c) LINEAR TECHNOLOGY CORPORATION 1999 |
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