19-4149; Rev 1; 8/08 Single- and Dual-Bidirectional Low-Level Translator The MAX13046E/MAX13047E 15kV ESD-protected bidirectional level translators provide level shifting for data transfer in a multivoltage system. The MAX13046E is a single-channel translator, and the MAX13047E is a dual-channel translator. Externally applied voltages, VCC and VL, set the logic level on either side of the device. The MAX13046E/MAX13047E utilize a transmission-gate-based design to allow data translation in either direction (VLVCC) on any single data line. The MAX13046E/MAX13047E accept VL from +1.1V to the minimum of either +3.6V or (VCC + 0.3V), and VCC from +1.65V to +5.5V, making these devices ideal for data transfer between low-voltage ASICs/PLDs and higher voltage systems. The MAX13046E/MAX13047E feature a shutdown mode that reduces supply current to less than 1A thermal short-circuit protection, and 15kV ESD protection on the VCC side for enhanced protection in applications that route signals externally. The MAX13046E/MAX13047E operate at a guaranteed data rate of 8Mbps when pushpull driving is used. Features Bidirectional Level Translation Operation Down to +1.1V on VL Ultra-Low Supply Current in Shutdown Mode 1A (max) Guaranteed Push-Pull Driving Data Rate 8Mbps (+1.2V VL +3.6V, VCC +5.5V) 16Mbps (+1.8V VL VCC +3.3V) Extended ESD Protection on the I/O VCC Lines 15kV Human Body Model 15kV IEC61000-4-2 Air-Gap Discharge Method 8kV IEC61000-4-2 Contact Discharge Low Supply Current Short-Circuit Protection Space-Saving DFN and UTQFN Packages Pin Configurations TOP VIEW MAX13046E The MAX13046E is available in a 6-pin DFN package, and the MAX13047E is available in a 10-pin UTQFN. Both devices are specified over the extended -40C to +85C operating temperature range. VCC SHDN I/O VCC 6 5 4 + Applications 1 2 3 VL1 GND I/O VL DFN 1mm x 1.5mm I2C and 1-Wire(R) Level Translation CMOS Logic-Level Translation MAX13047E Cell Phones Portable Devices 1-Wire is a registered trademark of Maxim Integrated Products, Inc. N.C. VCC 7 6 I/O VCC1 8 5 I/O VCC2 GND 9 4 SHDN I/O VL1 10 3 N.C. + Typical Application Circuits appear at end of data sheet. 1 2 I/O VL2 VL UTQFN 1.4mm x 1.8mm Ordering Information/Selector Guide PART PIN-PACKAGE NUMBER OF CHANNELS TOP MARK MAX13046EELT+ 6 DFN (1mm x 1.5mm) 1 OC MAX13047EEVB+ 10 UTQFN (1.4mm x 1.8mm) 2 AAC Note: All devices are specified over the extended -40C to +85C operating temperature range. +Denotes a lead-free/RoHS-compliant package. EP = Exposed pad. ________________________________________________________________ Maxim Integrated Products For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim's website at www.maxim-ic.com. 1 MAX13046E/MAX13047E General Description MAX13046E/MAX13047E Single- and Dual-Bidirectional Low-Level Translator ABSOLUTE MAXIMUM RATINGS (All voltages referenced to GND.) VCC ...........................................................................-0.3V to +6V VL ..............................................................................-0.3V to +4V I/O VCC .......................................................-0.3V to (VCC + 0.3V) I/O VL ............................................................-0.3V to (VL + 0.3V) SHDN........................................................................-0.3V to +6V Short-Circuit Duration I/O VL, I/O VCC to GND...........Continuous Power Dissipation (TA = +70C) 6-Pin DFN (derate 2.1mW/C above +70C) .............168mW 10-Pin UTQFN (derate 6.9mW/C above +70C).........559mW Junction-to-Ambient Thermal Resistance (JA) (Note 1) 6-Pin DFN .................................................................477C/W 10-Pin UTQFN ...........................................................20.1C/W Junction-to-Ambient Thermal Resistance (JC) (Note 1) 6-Pin DFN ................................................................20.1C/W 10-Pin UTQFN .........................................................143.1C/W Operating Temperature Range ...........................-40C to +85C Junction Temperature ......................................................+150C Storage Temperature Range .............................-65C to +150C Lead Temperature (soldering, 10s) .................................+300C Note 1: Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7, using a four-layer board. For detailed information on package thermal considerations, refer to www.maxim-ic.com/thermal-tutorial. Stresses beyond those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS (VCC = +1.65V to +5.5V, VL = +1.1V to minimum of either +3.6V or ((VCC + 0.3V)), I/O VL and I/O VCC are unconnected, TA = -40C to +85C, unless otherwise noted. Typical values are VCC = +3.3V, VL = +1.8V at TA = +25C.) (Notes 2, 3) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS POWER SUPPLY VL Supply Range VCC Supply Range Supply Current from VCC Supply Current from VL VL VCC > 3.3V 1.1 VCC 3.3V 1.1 VCC 3.6V VCC + 0.3V 1.65 IQVCC 5.5 V 10 A 15 A ISD-VCC TA = +25C, SHDN = GND 0.03 1 A VL Shutdown-Mode Supply Current ISD-VL TA = +25C, SHDN = GND 0.03 1 A I/O VL and I/O VCC Shutdown-Mode Leakage Current ISD-LKG TA = +25C, SHDN = GND 0.02 0.5 A TA = +25C 0.02 0.1 A VCC Shutdown-Mode Supply Current IQVL V SHDN Input Leakage ESD PROTECTION Human Body Model 15V I/O VCC (Note 4) IEC 61000-4-2 Air-Gap Discharge 15V IEC 61000-4-2 Contact Discharge 8V All Other Pins Human Body Model kV 2 kV LOGIC-LEVEL THRESHOLDS I/O VL Input-Voltage High VIHL I/O VL Input-Voltage Low VILL 2 VL 0.2 _______________________________________________________________________________________ V 0.15 V Single- and Dual-Bidirectional Low-Level Translator (VCC = +1.65V to +5.5V, VL = +1.1V to minimum of either +3.6V or ((VCC + 0.3V)), I/O VL and I/O VCC are unconnected, TA = -40C to +85C, unless otherwise noted. Typical values are VCC = +3.3V, VL = +1.8V at TA = +25C.) (Notes 2, 3) PARAMETER SYMBOL CONDITIONS VIHC I/O VCC Input-Voltage Low VILC I/O VL Output-Voltage High VOHL I/O VL source current = 20A, VI/O VCC > VCC - 0.4V I/O VL Output-Voltage Low VOLL I/O VL sink current = 1mA, VI/O VCC < 0.15V I/O VCC Output-Voltage High VOHC I/O VCC source current = 20A, VI/O VL > VL - 0.2V I/O VCC Output-Voltage Low VOLC I/O VCC sink current = 1mA, VI/O VL < 0.15V VIH-SHDN SHDN Input-Voltage Low VIL-SHDN TYP MAX VCC 0.4 I/O VCC Input-Voltage High SHDN Input-Voltage High MIN V 0.15 0.67 x VL 0.67 x VCC VL - 0.2 VL - 0.1 V V 0.4 1.1 VL < 1.2 V V 0.4 VL > 1.2 UNITS V V 0.15 V 80 250 VCC Shutdown Threshold Low VTH_L_VCC VCC falling, VL = +3.3V 0.5 0.8 1.1 V VCC Shutdown Threshold High VTH_H_VCC VCC rising, VL = +3.3V VTH_VL 0.3 0.6 0.9 V 0.35 0.75 1.06 V 6 10 15.5 k I/O VL-to-I/O VCC Resistance VL Shutdown Threshold Pullup Resistance VCC = VL = +3.3V RISE/FALL-TIME ACCELERATOR STAGE Accelerator Pulse Duration 20 ns VL = 1.7V 13 I/O VCC Output-Accelerator Source Impedance VCC = 2.2V 17 I/O VL Output-Accelerator Source Impedance VL = 3.2V 6 I/O VCC Output-Accelerator Source Impedance VCC = 3.6V 10 I/O VL Output-Accelerator Source Impedance _______________________________________________________________________________________ 3 MAX13046E/MAX13047E ELECTRICAL CHARACTERISTICS (continued) MAX13046E/MAX13047E Single- and Dual-Bidirectional Low-Level Translator TIMING CHARACTERISTICS FOR +1.2V VL MINIMUM OF EITHER +3.6V OR (VCC + 0.3V) (VCC 5.5V, +1.2V VL minimum of either +3.6V or ((VCC + 0.3V)), RS = 50, RL = 1M, CL = 15pF, TA = -40C to +85C, unless otherwise noted. Typical values are VCC = +3.3V, VL = +1.8V at TA = +25C.) (Notes 2, 3, 5) PARAMETER SYMBOL I/O VCC Rise Time tRVCC I/O VCC Fall Time tFVCC I/O VL Rise Time tRVL I/O VL Fall Time tFVL tPD-VL-VCC CONDITIONS Push-pull driving, Figure 1a MAX 7 25 400 Push-pull driving, Figure 1a 6 37 Open-drain driving, Figure 1c 20 50 Push-pull driving, Figure 1b Open-drain driving, Figure 1d 8 30 180 400 Push-pull driving, Figure 1 3 56 Open-drain driving, Figure 1d 30 60 5 30 210 1000 4 30 190 1000 Driving I/O VL tPD-VCC-VL Driving I/O VCC tSKEW Each translator equally loaded Push-pull driving Open-drain driving Push-pull driving Open-drain driving Push-pull driving 20 Open-drain driving 50 Push-pull driving Maximum Data Rate TYP 170 Open-drain driving, Figure 1c Propagation Delay Channel-to-Channel Skew MIN Open-drain driving UNITS ns ns ns ns ns ns 8 Mbps 500 kbps TIMING CHARACTERISTICS FOR +1.1V VL +1.2V (VCC 5.5V, +1.1V VL +1.2V, RS = 50, RL = 1M, CL = 15pF, TA = -40C to +85C, unless otherwise noted. Typical values are VCC = +3.3V, VL = +1.8V at TA = +25C.) (Notes 2, 3, 5) PARAMETER SYMBOL I/O VCC Rise Time tRVCC I/O VCC Fall Time tFVCC I/O VL Rise Time tRVL I/O VL Fall Time tFVL CONDITIONS TYP MAX 7 200 170 400 Push-pull driving, Figure 1a 6 37 Open-drain driving, Figure 1c 20 50 Open-drain driving, Figure 1c Push-pull driving, Figure 1b 8 30 180 400 Push-pull driving, Figure 1 3 30 Open-drain driving, Figure 1d 30 60 Open-drain driving, Figure 1d tPD-VL-VCC Driving I/O VL tPD-VCC-VL Driving I/O VCC Propagation Delay Channel-to-Channel Skew Maximum Data Rate 4 tSKEW MIN Push-pull driving, Figure 1a Each translator equally loaded Push-pull driving Open-drain driving Push-pull driving Open-drain driving 5 200 210 1000 4 200 190 1000 Push-pull driving 20 Open-drain driving 50 UNITS ns ns ns ns ns ns Push-pull driving 1.2 Mbps Open-drain driving 500 kbps _______________________________________________________________________________________ Single- and Dual-Bidirectional Low-Level Translator (+1.8V VL VCC +3.3V, RS = 50, RL = 1M, CL = 15pF, TA = -40C to +85C, unless otherwise noted. Typical values are VCC = +3.3V, VL = +1.8V at TA = +25C.) (Notes 2, 3, 5) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS ns I/O VCC Rise Time tRVCC Push-pull driving, Figure 1a 15 I/O VCC Fall Time tFVCC Push-pull driving, Figure 1a 15 ns I/O VL Rise Time tRVL Push-pull driving, Figure 1b 15 ns tFVL ns I/O VL Fall Time Propagation Delay Channel-to-Channel Skew Maximum Data Rate Push-pull driving, Figure 1b 15 tPD-VL-VCC Push-pull driving, driving I/O VL 15 tPD-VCC-VL Push-pull driving, driving I/O VCC 15 tSKEW Push-pull driving, each translator equally loaded 10 Push-pull driving 16 ns ns Mbps Note 2: All units are 100% production tested at TA = +25C. Limits over the operating temperature range are guaranteed by design and not production tested. Note 3: For normal operation, ensure VL < (VCC + 0.3V). During power-up, VL > (VCC + 0.3V) does not damage the device. Note 4: ESD protection is guaranteed by design. To ensure maximum ESD protection, place a 1F ceramic capacitor between VCC and GND. See Typical Application Circuits. Note 5: Timing is measured using 10% of input to 90% of output. _______________________________________________________________________________________ 5 MAX13046E/MAX13047E TIMING CHARACTERISTICS FOR +1.8V VL VCC +3.3V Typical Operating Characteristics (VCC = +3.3V, VL = +1.8V, RL = 1M, CL = 15pF, push-pull driving data rate = 8Mbps, TA = +25C, unless otherwise noted.) VL DYNAMIC SUPPLY CURRENT vs. VCC SUPPLY VOLTAGE (PUSH-PULL DRIVING ONE I/O VCC) 200 150 100 150 100 50 500 0 2.75 3.30 3.85 4.40 4.95 VCC SUPPLY VOLTAGE (V) 50 40 30 20 180 160 10 1.2 1.9 2.6 VL SUPPLY VOLTAGE (V) 140 120 100 80 60 300 10 35 TEMPERATURE (C) 60 85 -40 800 600 400 50 60 85 tFVCC 15 10 tRVCC 0 0 0 20 5 200 20 10 35 TEMPERATURE (C) 25 MAX13046E/7E toc08 1000 -15 RISE/FALL TIME vs. CAPACITIVE LOAD (PUSH-PULL DRIVING ONE I/O VL) RISE/FALL TIME (ns) 40 20 30 40 CAPACITIVE LOAD (pF) 100 0 -15 1200 VCC SUPPLY CURRENT (A) 60 10 150 VCC DYNAMIC SUPPLY CURRENT vs. CAPACITIVE LOAD (PUSH-PULL DRIVING ONE I/O VL) 80 0 200 50 -40 3.3 MAX13046E/7E toc07 100 250 40 VL DYNAMIC SUPPLY CURRENT vs. CAPACITIVE LOAD (PUSH-PULL DRIVING ONE I/O VL) 120 3.3 350 0 1.2 1.9 2.6 VL SUPPLY VOLTAGE (V) VL DYNAMIC SUPPLY CURRENT vs. TEMPERATURE (PUSH-PULL DRIVING ONE I/O VCC) 20 0 6 5.50 MAX13046E/7E toc05 60 2.75 3.30 3.85 4.40 4.95 VCC SUPPLY VOLTAGE (V) 200 VL SUPPLY CURRENT (A) MAX13046E/7E toc04 VCC SUPPLY CURRENT (A) 70 2.20 VL DYNAMIC SUPPLY CURRENT vs. TEMPERATURE (PUSH-PULL DRIVING ONE I/O VL) VCC DYNAMIC SUPPLY CURRENT vs. VL SUPPLY VOLTAGE (PUSH-PULL DRIVING ONE I/O VCC) 80 200 0 1.65 5.50 300 MAX13046E/7E toc06 2.20 VL SUPPLY CURRENT (A) 1.65 400 100 50 0 MAX13046E/7E toc03 200 600 MAX13046E/7E toc09 250 MAX13046E/7E toc02 VL SUPPLY CURRENT (A) 300 250 VL SUPPLY CURRENT (A) MAX13046E/7E toc01 350 VCC DYNAMIC SUPPLY CURRENT vs. VL SUPPLY VOLTAGE (PUSH-PULL DRIVING ONE I/O VL) VCC SUPPLY CURRENT (A) VL DYNAMIC SUPPLY CURRENT vs. VCC SUPPLY VOLTAGE (PUSH-PULL DRIVING ONE I/O VL) VL SUPPLY CURRENT (A) MAX13046E/MAX13047E Single- and Dual-Bidirectional Low-Level Translator 0 10 20 30 40 CAPACITIVE LOAD (pF) 50 0 10 20 30 40 CAPACITIVE LOAD (pF) _______________________________________________________________________________________ 50 Single- and Dual-Bidirectional Low-Level Translator RISE/FALL TIME vs. CAPACITIVE LOAD (PUSH-PULL DRIVING ONE I/O VCC) 4 3 2 8 6 tFVL 4 2 1 0 10 20 30 40 CAPACITIVE LOAD (pF) 50 3.0 2.5 2.0 1.5 1.0 0.5 0 0 3.5 MAX13046E/7E toc12 tRVL 10 RISE/FALL TIME (ns) 5 MAX13046E/7E toc11 6 PROPAGATION DELAY (ns) 12 MAX13046E/7E toc10 7 PROPAGATION DELAY vs. CAPACITIVE LOAD (PUSH-PULL DRIVING ONE I/O VCC) PROPAGATION DELAY (ns) PROPAGATION DELAY vs. CAPACITIVE LOAD (PUSH-PULL DRIVING ONE I/O VL) 0 0 10 20 30 40 CAPACITIVE LOAD (pF) RAIL-TO-RAIL DRIVING (DRIVING ONE I/O VL) 50 0 10 20 30 40 CAPACITIVE LOAD (pF) 50 EXISTING SHUTDOWN MODE MAX13046E/7E toc13 MAX13046E/7E toc14 1V/div 1V/div I/O VL I/O VL 2V/div I/O VCC 1V/div I/O VCC 1V/div SHDN 25ns/div 250ns/div _______________________________________________________________________________________ 7 MAX13046E/MAX13047E Typical Operating Characteristics (continued) (VCC = +3.3V, VL = +1.8V, RL = 1M, CL = 15pF, push-pull driving data rate = 8Mbps, TA = +25C, unless otherwise noted.) Single- and Dual-Bidirectional Low-Level Translator MAX13046E/MAX13047E MAX13046E Pin Description MAX13046E DFN NAME 1 VL FUNCTION VL Input Supply Voltage. Bypass VL with a 0.1F ceramic capacitor located as close as possible to the input. 2 GND Ground 3 I/O VL Input/Output. Referenced to VL. 4 I/O VCC 5 SHDN Shutdown Input. Drive SHDN high to enable the device. Drive SHDN low to put the device in shutdown mode. 6 VCC VCC Input Supply Voltage. Bypass VCC with a 1F ceramic capacitor located as close as possible to the input for full ESD protection. If full ESD protection is not required, bypass VCC with a 0.1F ceramic capacitor. Input/Output. Referenced to VCC. MAX13047E Pin Description MAX13047E UTQFN NAME 1 I/O VL2 2 VL 3, 7 N.C. 4 SHDN 5 I/O VCC2 6 VCC 8 I/O VCC1 9 GND 10 I/O VL1 -- EP FUNCTION Input/Output 2. Referenced to VL. VL Input Supply Voltage. Bypass VL with a 0.1F ceramic capacitor located as close as possible to the input. Not Connected. Internally not connected. Enable Input. Drive SHDN high to enable the device. Drive SHDN low to put the device in shutdown mode. Input/Output 2. Referenced to VCC. VCC Input Supply Voltage. Bypass VCC with a 1F ceramic capacitor located as close as possible to the input for full ESD protection. If full ESD protection is not required, bypass VCC with a 0.1F ceramic capacitor. Input/Output 1. Referenced to VCC. Ground Input/Output 1. Referenced to VL. Exposed Pad. Connect EP to GND. Detailed Description The MAX13046E/MAX13047E 15kV ESD-protected bidirectional level translators provide level shifting for data transfer in a multivoltage system. The MAX13046E is a single-channel translator and the MAX13047E is a dual-channel translator. Externally applied voltages, VCC and VL, set the logic level on either side of the device. The MAX13046E/MAX13047E utilize a transmission-gate-based design to allow data translation in either direction (VL VCC) on any single data line. The MAX13046E/MAX13047E accept VL from +1.1V to the minimum of either +3.6V or (VCC + 0.3V) and VCC from 8 +1.65V to +5.5V, making these devices ideal for data transfer between low-voltage ASICs/PLDs and higher voltage systems. The MAX13046E/MAX13047E feature a shutdown mode that reduces supply current to less than 1A thermal short-circuit protection, and 15kV ESD protection on the VCC side for enhanced protection in applications that route signals externally. The MAX13046E/MAX13047E operate at a guaranteed data rate of 8Mbps when pushpull driving is used. See the Functional Diagram. _______________________________________________________________________________________ Single- and Dual-Bidirectional Low-Level Translator VCC VL PU1 ONE-SHOT RISE-TIME ACCELERATOR ONE-SHOT RISE-TIME ACCELERATOR 10k PU2 10k GATE BIAS I/O VL I/O VCC N SHDN Level Translation For proper operation, ensure that +1.65V V CC +5.5V and +1.1V VL the minimum of either +3.6V or (VCC + 0.3V). During power-up sequencing, VL (VCC + 0.3V) does not damage the device. The speed of the rise time accelerator circuitry limits the maximum data rate for the MAX13046E/MAX13047E to 16Mbps. Rise-Time Accelerators The MAX13046E/MAX13047E have an internal rise-time accelerator, allowing operation up to 16Mbps. The risetime accelerators are present on both sides of the device and act to speed up the rise time of the input and output of the device, regardless of the direction of the data. The triggering mechanism for these accelerators is both level and edge sensitive. To guarantee operation of the rise time accelerators the maximum parasitic capacitance should be less than 200pF on the I/O lines. Shutdown Mode Drive SHDN low to place the MAX13046E/MAX13047E in shutdown mode and drive SHDN high for normal operation. Activating the shutdown mode disconnects the internal 10k pullup resistors on the I/O VCC and I/O VL lines. This forces the I/O lines to a high-impedance GND state, and decreases the supply current to less than 1A. The high-impedance I/O lines in shutdown mode allow for use in a multidrop network. The MAX13046E/ MAX13047E have a diode from each I/O to the corresponding supply rail and GND. Therefore, when in shutdown mode, do not allow the voltage at I/O VL to exceed (VL + 0.3V), or the voltage at I/O VCC to exceed (VCC + 0.3V). Operation with One Supply Disconnected Certain applications require sections of circuitry to be disconnected to save power. When VL is connected and VCC is disconnected or connected to ground, the device enters shutdown mode. In this mode, I/O VL can still be driven without damage to the device; however, data does not translate from I/O VL to I/O VCC. If VCC falls more than VTH_L_VCC below VL, the device disconnects the pullup resistors at I/O VL and I/O VCC. To achieve the lowest possible supply current from VL when VCC is disconnected, it is recommended that the voltage at the VCC supply input be approximately equal to GND. When VCC is connected and VL is less than VTH_VL, the device enters shutdown mode. In this mode, I/O VCC can still be driven without damage to the device; however, data does not translate from I/O VCC to I/O VL. _______________________________________________________________________________________ 9 MAX13046E/MAX13047E Functional Diagram MAX13046E/MAX13047E Single- and Dual-Bidirectional Low-Level Translator VL VCC VL VL VCC VCC VL SHDN MAX13046E/ MAX13047E RS 50 VCC SHDN MAX13046E/ MAX13047E DATA I/O VCC I/O VL I/O VCC I/O VL RL GND RS 50 DATA CL CL I/O VL (tRISE, tFALL < 10ns) RL GND I/O VCC (tRISE, tFALL < 10ns) tPD-VL-VCC tPD-VL-VCC I/O VCC tPD-VCC-VL tPD-VCC-VL tRVL tFVL I/O VL tRVCC tFVCC Figure 1a. Rail-to-Rail Driving I/O VL Figure 1b. Rail-to-Rail Driving I/O VCC When VCC is disconnected or connected to ground, I/O VCC must not be driven more than VCC + 0.3V. When VL is disconnected or connected to ground, I/O VL must not be driven more than VL + 0.3V. operation, shutdown mode, and powered down. The I/O VCC lines of the MAX13046E/MAX13047E are characterized for protection to the following limit: Short-Circuit Protection Thermal-overload detection protects the MAX13046E/ MAX13047E from short-circuit fault conditions. In the event of a short-circuit fault, when the junction temperature (TJ) exceeds +150C, the device enters shutdown mode. When the device has cooled to below +140C, normal operation resumes. 15kV ESD Protection ESD protection structures are incorporated on all pins to protect against electrostatic discharges encountered during handling and assembly. The ESD structures withstand electrostatic discharge in all states: normal 10 * 15kV using the Human Body Model ESD Test Conditions ESD performance depends on a variety of conditions. Contact Maxim for a reliability report that documents test setup, test methodology, and test results. Human Body Model Figure 2a shows the Human Body Model, and Figure 2b shows the current waveform it generates when discharged into a low-impedance state. This model consists of a 100pF capacitor charged to the ESD voltage of interest that is then discharged into the test device through a 1.5k resistor. ______________________________________________________________________________________ Single- and Dual-Bidirectional Low-Level Translator VCC VL VL MAX13046E/MAX13047E VL VCC VCC VL SHDN VCC SHDN MAX13046E/ MAX13047E MAX13046E/ MAX13047E DATA DATA I/O VCC I/O VL I/O VCC I/O VL RL GND CL I/O VL CL RL GND I/O VCC tPD-VL-VCC tPD-VCC-VL tPD-VL-VCC tPD-VCC-VL I/O VCC I/O VL tRVCC tFVCC Figure 1c. Open-Drain Driving I/O VL tRVL tFVL Figure 1d. Open-Drain Driving I/O VCC IEC 61000-4-2 The IEC 61000-4-2 standard covers ESD testing and performance of finished equipment; it does not specifically refer to integrated circuits. The MAX13046E/MAX13047E help to design equipment that meets Level 4 of IEC 61000-4-2 without the need for additional ESD-protection components. The major difference between tests done using the Human Body Model and IEC 61000-4-2 is higher peak current in IEC 61000-4-2 because series resistance is lower in the IEC 61000-4-2 model. Hence, the ESD withstand voltage measured to IEC 61000-4-2 can be lower than that measured using the Human Body Model. Figure 3a shows the IEC 61000-4-2 model, and Figure 3b shows the current waveform for the 8kV, IEC 61000-4-2, Level 4, ESD contact-discharge test. The AirGap test involves approaching the device with a charged probe. The contact-discharge method connects the probe to the device before the probe is energized. Applications Information Power-Supply Decoupling To reduce ripple and the chance of transmitting incorrect data, bypass VL and VCC to ground with a 0.1F ceramic capacitor. To ensure full 15kV ESD protection, bypass VCC to ground with a 1F ceramic capacitor. Place all capacitors as close as possible to the power-supply inputs. I2C Level Translation The MAX13046E/MAX13047E level shifts the data present on the I/O lines between +1.1V and +5.5V, making them ideal for level translation between a low-voltage ASIC and an I2C device. A typical application involves interfacing a low-voltage microprocessor to a +3V or +5V D/A converter, such as the MAX517. 1-Wire Interface Translation The MAX13046E/MAX13047E are ideal for level translation between a low-voltage ASIC and 1-Wire device. A ______________________________________________________________________________________ 11 RC 1M CHARGE-CURRENTLIMIT RESISTOR HIGHVOLTAGE DC SOURCE Cs 100pF RD 1500 RC 50M TO 100M DISCHARGE RESISTANCE DEVICE UNDER TEST Ir HIGHVOLTAGE DC SOURCE Cs 150pF DEVICE UNDER TEST STORAGE CAPACITOR Figure 3a. IEC 61000-4-2 ESD Test Model Figure 2a. Human Body ESD Test Model IP 100% 90% DISCHARGE RESISTANCE CHARGE-CURRENTLIMIT RESISTOR STORAGE CAPACITOR RD 330 I 100% 90% PEAK-TO-PEAK RINGING (NOT DRAWN TO SCALE) IPEAK MAX13046E/MAX13047E Single- and Dual-Bidirectional Low-Level Translator AMPERES 36.8% 10% 0 10% 0 tRL TIME tDL CURRENT WAVEFORM Figure 2b. Human Body Current Waveform typical application involves interfacing a low-voltage microprocessor to an external memory, such as the DS2502. The maximum data rate depends on the 1-Wire device. For the DS2502, the maximum data rate is 16.3kbps. A 5k pullup resistor is recommended when interfacing with the DS2502. Push-Pull vs. Open-Drain Driving The MAX13046E/MAX13047E can be driven in a pushpull or open-drain configurations. For open-drain configuration, internal 10k resistors pull up I/O VL and I/O VCC to their respective power supplies. See the Timing Characteristics table for maximum data rates when using open-drain drivers. tr = 0.7ns TO 1ns 30ns t 60ns Figure 3b. IEC 61000-4-2 ESD Generator Current Waveform PCB Layout The MAX13046E/MAX13047E require good PCB layout for proper operation and optimal rise/fall time performance. Ensure proper high-frequency PCB layout even when operating at low data rates. Driving High-Capacitive Load Capacitive loading on the I/O lines impacts the rise time (and fall time) of the MAX13046E/MAX13047E when driving the signal lines. The actual rise time is a function of the load capacitance, parasitic capacitance, the supply voltage, and the drive impedance of the MAX13046E/ MAX13047E. Operating the MAX13046E/MAX13047E at a low data rate does NOT increase capacitive load driving capability. 12 ______________________________________________________________________________________ Single- and Dual-Bidirectional Low-Level Translator +1.8V +3.3V 0.1F 1F VL VCC SHDN +1.8V SYSTEM +3.3V SYSTEM MAX13046E DATA I/O VL DATA I/O VCC +1.8V +3.3V 0.1F 1F VL VCC SHDN +1.8V SYSTEM +3.3V SYSTEM MAX13047E DATA I/O VL1 I/O VCC1 I/O VL2 I/O VCC2 DATA ______________________________________________________________________________________ 13 MAX13046E/MAX13047E Typical Application Circuits MAX13046E/MAX13047E Single- and Dual-Bidirectional Low-Level Translator Package Information Chip Information PROCESS: BiCMOS 14 For the latest package outline information and land patterns, go to www.maxim-ic.com/packages. PACKAGE TYPE PACKAGE CODE DOCUMENT NO. 6 DFN L611-1 21-0147 10 UTQFN V101A1CN-1 21-0028 ______________________________________________________________________________________ Single- and Dual-Bidirectional Low-Level Translator REVISION NUMBER REVISION DATE 0 5/08 Initial release 8/08 Removing future product asterisks from MAX13047, changing Electrical Characteristics Table, packaging changes, changing ESD information 1 DESCRIPTION PAGES CHANGED 1-4, 6, 10 Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 15 (c) 2008 Maxim Integrated Products is a registered trademark of Maxim Integrated Products, Inc. MAX13046E/MAX13047E Revision History