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| MIC2559 Micrel MIC2559 PCMCIA Dual Card Socket VPP Switching Matrix Not Recommended for New Designs General Description The MIC2559 Dual VPP Matrix switches the four voltages required by PCMCIA (Personal Computer Memory Card International Association) card VPP1 and VPP2 Pins. The MIC2559 provides selectable 0V, 3.3V, 5.0V, or 12.0V (5%) from the system power supply to VPP1 and VPP2. Output voltage is selected by two digital inputs per VPP pin. Output current ranges up to 120mA. Four output states, VPP, VCC, high impedance, and active logic low are available, and VPP1 is independent of VPP2. An auxiliary control input determines whether the high impedance (open) state or low logic state is asserted. In standby mode or full operation, the device draws very little quiescent current, typically less than 1A. The MIC2559 is available in a 14-pin SOIC. Features * * * * * * * * * * Complete PCMCIA VPP Switch Matrix in a Single IC Dual Matrix allows independent VPP1 and VPP2 Digital Selection of 0V, VCC, VPP, or High Imped- ance Output No VPPOUT Overshoot or Switching Transients Break-Before-Make Switching Ultra Low Power Consumption 120mA V PP (12V) Output Current Optional Active Source Clamp for Zero Volt Condition 3.3V or 5V Supply Operation 14-Pin SOIC Package Ordering Information Applications * * PCMCIA VPP Pin Voltage Switch Power Supply Management Part Number MIC2559BM MIC2559BM T&R Temperature Range -40C to +85C -40C to +85C Package 14-pin SOIC 14-SO Tape & Reel* * 2,500 Parts per reel. Typical Application VPP IN VCC +12V +3.3V or +5V VDD +5V Pin Configuration VPP OUT1 NC +VCC1 VPP IN +VCC2 GND VPP OUT2 14 2 13 0.1F VPP OUT 1 2 14 13 3 12 MIC2559 4 11 5 6 7 10 9 8 0.1F 1F 1F 3 12 MIC2559 4 11 5 6 7 10 9 8 Hi-Z/ Low 1 Control EN01 EN11 Hi-Z/ Low 2 Control EN02 EN12 VDD Hi-Z/Low1 EN01 EN11 Hi-Z/Low2 EN02 EN12 VPP OUT 2 0.1F EN1 0 0 0 1 1 EN0 Hi-Z/Low VPP OUT 0 0 1 0 1 0 1 x x x 0V, (Sink current) Hi-Z (No Connect) V V CC PP (3.3V or 5.0V) Hi-Z (No Connect) 2-16 April 1998 MIC2559 Micrel (Notes 1 and 2) 800 mW 4 mW/C -65C to +150C 125C -40C to +85C 260C Supply Voltage, VPP IN VCC VDD Logic Input Voltages Output Current (each Output) VPP OUT = 12V VPP OUT = VCC 15V 7.5V 7.5V -5V toVDD 600mA 250mA Absolute Maximum Ratings Power Dissipation, TAMBIENT 25C Derating Factors (To Ambient) Storage Temperature Operating Temperature (Die) Operating Temperature (Ambient) Lead Temperature (5 sec) Logic Block Diagram VDD 14 VPP IN 4 EN11 2 11 VDD VDD VPP IN 3 VCC1 EN01 12 VDD VDD 1 VPP OUT1 HiZ/ LOW1 13 VDD EN12 VPP IN 8 VDD VDD VPP IN 5 VCC2 EN02 9 VDD VDD 7 VPP OUT2 HiZ/ LOW2 10 6 GND April 1998 2-17 MIC2559 Micrel (Over operating temperature range with VDD = VCC= 5V, VPP IN = 12 V unless otherwise specified.) Conditions Min Typ Max Units Electrical Characteristics: Symbol INPUT VIH VIL VIN (Max) IIN Logic 1 Input Voltage Logic 0 Input Voltage Input Voltage Range Input Current Parameter 2.2 0.8 -5 0 V < VIN < VDD VDD 1 V V V A EACH OUTPUT VOL IOUT, Hi-Z Clamp Low Output Voltage High Impedance Output Leakage Current Clamp Low Output Resistance EN0 = EN1 = HiZ = 0, ISINK = 1.6mA EN0 = EN1 = 0, HiZ = 1. 0 VPP OUT 12V Resistance to Ground. ISINK = 2mA EN0 = EN1 = 0, HiZ = 0. IPP OUT = -100 mA (Sourcing) TA = -40C to +60C IPP OUT = -100 mA (Sourcing) 1 0.4 10 V A ROC 130 250 RO Switch Resistance, VPP OUT = VCC Switch Resistance, VPP OUT = VPP IN 0.8 1.5 RO 0.5 1 SWITCHING TIME (See Figure 1) t1 t2 t3 t4 t5 t6 Delay + Rise Time Delay + Rise Time Delay + Fall Time Delay + Fall Time Output Turn-On Delay Output Turn-Off Delay VPP OUT = 0V to 5V (Notes 3, 5) VPP OUT = 5V to 12V (Notes 3, 5) VPP OUT = 12V to 5V (Notes 3, 5) VPP OUT = 5V to 0V (Notes 3, 5) VPP OUT = Hi-Z to 5V (Notes 4, 5) VPP OUT = 5V to Hi-Z (Notes 4, 5) 15 12 25 45 10 75 50 50 75 100 50 200 s s s s s ns POWER SUPPLY IDD ICC IPP VDD Supply Current VCC Supply Current IPP Supply Current IPP OUT = 0 VPP OUT1 = VPPOUT2 = 0 V or VPP . IPPOUT = 0. VPP OUT1 = VPPOUT2 = VCC - - - 1 1 10 A A A A 20 80 2-18 April 1998 MIC2559 Micrel Electrical Characteristics (continued) Symbol Parameter Conditions Min Typ Max Units POWER SUPPLY, continued VCC VDD VPP IN Operating Input Voltage Operating Input Voltage Operating Input Voltage 2.8 8.0 6 6 14.5 V V V NOTE 1: NOTE 2: NOTE 3: NOTE 4: NOTE 5: Functional operation above the absolute maximum stress ratings is not implied. Static-sensitive device. Store only in conductive containers. Handling personnel and equipment should be grounded to prevent damage from static discharge. With RL = 2.9k and COUT = 0.1F on VPP OUT. RL = 2.9k. RL is connected to VCC during t5, and is connected to ground during t6. Rise and fall times are measured to 90% of the difference of initial and final values. 2 3V Hi-Z/Low 0 3V EN0 0 3V EN1 0 12V VPP OUT 5V 0 t1 t2 t3 t4 t5 t6 Figure 1. Timing Diagram. April 1998 2-19 MIC2559 Micrel Applications Information PCMCIA VPP1 and VPP2 control is easily accomplished using the MIC2559 voltage selector/switch IC. Two control bits per VPP OUT pin determine output voltage and standby/ operate mode condition. Output voltages of 0V (defined as less than 0.4V), VCC (3.3V or 5V), VPP, or a high impedance state, are available. When either the high impedance or low voltage conditions are selected, the device switches into "sleep" mode and draws only nanoamperes of leakage current. The MIC2559 is a dual low-resistance power MOSFET switching matrix that operates from the computer system main power supply. Device power is obtained from VDD, which may be either 3.3V or 5V, and FET drive is obtained from VPP IN (usually +12V). Internal break-before-make switches determine the output voltage and device mode. VPP1 and VPP2 are completely indepenent from each other. Supply Bypassing For best results, bypass VCC and VPP IN inputs with 1F capacitors. Both VPP OUT pins should have a 0.01F to 0.1F capacitor for noise reduction and electrostatic discharge (ESD) damage prevention. Larger values of output capacitor will create large current spikes during transitions, requiring larger bypass capacitors on the VCC and VPP IN pins. 5V System Power 3.3V Supply 12V EN01 EN11 PCMCIA Card Slot A MIC2558 MIC2559 VPP IN VCC 5V System Power Supply 12V EN01 EN11 PCMCIA Card Slot A MIC2558 MIC2559 VPP IN VCC VCC Switch VCC VPP1 EN02 EN12 VPP2 PCMCIA Card Slot Controller VCC EN01 EN11 VPP IN VCC VPP1 PCMCIA Card Slot B MIC2558 MIC2559 VCC Select and Switch VCC EN02 EN12 VPP2 VPP1 Figure 3. MIC2559 Typical two slot PCMCIA application with single 5.0V VCC. PCMCIA Implementation The Personal Computer Memory Card International Association (PCMCIA) specification, version 2.0 (September, 1991), requires two VPP supply pins per PCMCIA slot. VPP is primarily used for programming Flash (EEPROM) memory cards. The two VPP supply pins may be programmed to different voltages. Fully implementing PCMCIA specifications requires a MIC2559 and a controller. Figure 2 shows this full configuration, supporting both 5.0V and 3.3V VCC operation. Figure 3 is a simplified design with fixed VCC = 5V. When a memory card is initially inserted, it should receive VCC -- usually 5.0V 5%. The card sends a handshaking data stream to the controller, which then determines whether or not this card requires VPP and if the card is designed for 5.0V or 3.3V VCC. If the card uses 3.3V VCC, the controller commands this change, which is reflected on the VCC pins of both the PCMCIA slot and the MIC2559. During Flash memory programming, the PCMCIA controller outputs a (1,0) to one or both halves of the MIC2559, which connects VPP IN to VPP OUT1 and/or VPP OUT2. The low ON resistance of the MIC2559 switch requires only a small bypass capacitor on the VPP OUT pins, with the main filtering 2-20 April 1998 EN02 EN12 VPP2 PCMCIA Card Slot Controller VCC Select and Switch VCC EN01 EN11 VPP IN VCC VPP1 PCMCIA Card Slot B MIC2558 MIC2559 EN02 EN12 VPP2 Figure 2. MIC2559 Typical two slot PCMCIA application with dual VCC (5.0V or 3.3V). MIC2559 action performed by a large filter capacitor on VPP IN. The VPP OUT transition from VCC to 12.0V typically takes 25S. After programming is completed, the controller outputs a (0,1) to the MIC2559, which then reduces VPP OUT to the VCC level. Break-before-make switching action reduces switching transients and lowers maximum current spikes through the switch from the output capacitor. If no card is inserted, or the system is in sleep mode, the controller outputs either a (0,0) or a (1,1) to the MIC2559. Either input places the switch into shutdown mode, where current consumption drops even further. The HiZ/Low input controls the optional logic low output clamp. With HiZ/Low in the high state and EN0 = EN1 = 0, VPP OUT enters a high impedance (open) state. With HiZ/ Low in the low state and EN0 = EN1 = 0, VPP OUT is clamped to ground, providing a logic low signal. The clamp does not require any DC bias current for operation. VPP IN +12V Micrel MOSFET drive and bias voltage is derived from VPP IN. Internal device control logic is powered from VDD, which should be connected to the same supply voltage as the PCMCIA controller (normally either 3.3V or 5V). Output Current MIC2559 output switches are capable of far more current than usually needed in PCMCIA applications. PCMCIA VPP output current is limited primarily by switch resistance voltage drop (I x R) and the requirement that VPP OUT cannot drop more than 5% below nominal. VPP OUT will survive output short circuits to ground if VPP IN or VCC are current limited by the regulator that supplies these voltages. VDD +5V 2 0.1F VPP OUT 1 2 14 13 0.1F 1F 3 12 MIC2559 4 11 5 6 7 10 9 8 Hi-Z/ Low 1 Control EN01 EN11 Hi-Z/ Low 2 Control EN02 EN12 VPP OUT 2 0.1F 8 +V IN SHUTDOWN 3 SD INPUT OFF ON VOUT 1 MIC2951 + 100pF GND 4 7 220k 1% 2N2222 FB TTL Logic Level 300k 1% 3.3F High (V > 1.5V) VCC = 5.0V 470 k Low (V < 0.5V) VCC = 3.3V 180k 1% VCC Switching and Control Block Figure 3. Full PCMCIA Implementation of VPP and VCC switching using MIC2559 and MIC2951 voltage regulator. April 1998 2-21 |
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