IC-HD7SO16N

iC-HD7 QUAD DIFFERENTIAL LINE DRIVER Rev A5, Page 1/8 FEATURES o Complementary short-circuit-proof push-pull driver stages for RS422 and 24 V applications up to 2 MHz o Pin-compatible to 26LS31, xx7272 o Integrated line adaptation for high signal quality at 24 V o Moderate slew rate reduces EMI o High driving capability of typically 200 mA at 24 V o Output saturation of just 0.3 V at 40 mAdc o Tristate function for bus applications with excessive temperature shutdown o TTL-/CMOS-compatible Schmitt trigger inputs, voltage-proof to 40 V o 4.5 to 35 V single supply operation with low static power dissipation o Operating temperature from -25 to 125 °C (-40 °C is optional) APPLICATIONS o Line drivers for 24 V control engineering o Linear scales and encoders o Sensor systems PACKAGES SO16N RoHS compliant BLOCK DIAGRAM 4.5..35 V iC-HD7 NEN VB UNDERVOLTAGE & OVERTEMPERATURE DRIVER STAGES O1 NO1 LINE I1 O2 I2 NO2 O3 NO3 I4 O4 NO4 I3 PLC GND Copyright © 2010 iC-Haus http://www.ichaus.com iC-HD7 QUAD DIFFERENTIAL LINE DRIVER Rev A5, Page 2/8 DESCRIPTION iC-HD7 is a robust line driver for industrial 5 V and 24 V applications with four complementary output channels. For signal lines with a characteristic impedance of 30 to 140 Ω the integrated line adapter, optimized to 75 Ω, minimizes ringing effects which arise when there is no line termination. At a supply of 24 V the push-pull driver stages typically provide 200 mA to discharge the line and also have a low saturation voltage (of typically 200 mV with a 40 mA low-side load). The outputs are current limited and short-circuit-proof, shutting down with excessive temperature. For bus applications the driver stages can be switched to high impedance by a high at input NEN. The driver stage inputs have a Schmitt trigger characteristic and are compatible with CMOS and TTL levels. For test purposes the temperature monitor can be deactivated by applying a voltage of greater than 12 V to input NEN. The device contains internal ESD protection circuitry. PACKAGES SO16N, TSSOP20 PIN CONFIGURATION SO16N PIN FUNCTIONS No. Name Function 16 1 I1 2 15 VB I4 14 O1 3 NO1 4 O4 13 nc 5 NO4 12 NO2 6 NEN 11 O2 7 10 NO3 O3 8 9 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 I1 O1 NO1 nc NO2 O2 I2 GND I3 O3 NO3 NEN NO4 O4 I4 VB Input 1 Driver Output 1 Inverted Driver Output 1 Inverted Driver Output 2 Driver Output 2 Input 2 Ground Input 3 Driver Output 3 Inverted Driver Output 3 Function Input (low signal enables driver outputs) Inverted Driver Output 4 Driver Output 4 Input 4 +4.5 to +35 V Supply Voltage HD7 Code... ...yyww I2 GND I3 iC-HD7 QUAD DIFFERENTIAL LINE DRIVER Rev A5, Page 3/8 ABSOLUTE MAXIMUM RATINGS Beyond these values damage may occur; device operation is not guaranteed. Absolute Maximum Ratings are no Operating Conditions. Integrated circuits with system interfaces, e.g. via cable accessible pins (I/O pins, line drivers) are per principle endangered by injected interferences, which may compromise the function or durability. The robustness of the devices has to be verified by the user during system development with regards to applying standards and ensured where necessary by additional protective circuitry. By the manufacturer suggested protective circuitry is for information only and given without responsibility and has to be verified within the actual system with respect to actual interferences. Item No. Symbol Parameter Supply Voltage VB Voltage at Inputs I1...I4 Voltage at Input NEN Voltage at Outputs O1...O4, NO1...NO4 Current in Outputs O1...O4, NO1...NO4 ESD Susceptibility at all pins Junction Temperature Storage Temperature HBM, 100 pF discharged through 1.5 kΩ -40 -40 Conditions Min. 0 0 0 0 -500 Max. 40 VB VB VB 500 2 150 150 V V V V mA kV °C °C Unit G001 VB G002 Vin() G003 Vin() G004 V() G005 I() G006 Vd() G007 Tj G008 Ts THERMAL DATA Item No. T01 T02 Symbol Ta Rthja Parameter Operating Ambient Temperature (extended range to -40°C on request) Thermal Resistance Chip To Ambient SO16N surface mounted, no special heat sink Conditions Min. -25 110 Typ. Max. 125 °C K/W Unit All voltages are referenced to ground unless otherwise stated. All currents flowing into the device pins are positive; all currents flowing out of the device pins are negative. iC-HD7 QUAD DIFFERENTIAL LINE DRIVER Rev A5, Page 4/8 ELECTRICAL CHARACTERISTICS Operating Conditions: VB = 4.5...35 V, Tj = -40...125 °C, unless otherwise noted Item No. 001 002 003 004 005 006 007 Symbol Parameter Conditions Min. VB I(VB) I(VB)tri Vc()lo Vc()hi Vc()lo Vc()hi Permissible Supply Voltage Supply Current in VB Tristate Current Consumption in VB Clamp Voltage lo at NEN, Ix, NERR Clamp Voltage hi at NEN, Ix, NERR Clamp Voltage lo at O1..O4, NO1..NO4 Clamp Voltage hi at O1..O4, NO1..NO4 Saturation Voltage lo Saturation Voltage hi Driving Capability lo Driving Capability hi Short-Circuit Current lo Short-Circuit Current hi Output Resistance Slew-Rate lo/hi In/Out Propagation Delay lo/hi Delay Skew Output Leakage Current output Ox vs. NOx NEN = hi -35 -10 NEN = lo, outputs not loaded NEN = hi I() = -1 mA I() = 1 mA VB = 0 V, I() = -10 mA VB = 0 V, I() = 10 mA -1.2 VB + 0.3 -1.2 VB + 0.3 0.2 0.3 40 -90 -500 50 75 400 75 200 35 10 110 60 -60 4.5 3.8 2.7 -0.3 VB + 1.2 -0.3 VB + 1.2 0.6 0.7 90 -40 500 V V mA mA mA mA Ω V/µs ns ns uA Typ. Max. 35 5.5 V mA mA V V Unit Total Device Driver Outputs Ox, NOx (x = 1...4) 101 102 103 104 105 106 107 108 109 110 111 Vs()lo Vs()hi Iout()lo Iout()hi Isc()lo Isc()hi Rout() SR()lo, hi tp()lo, hi dtp() Ilk() I() = 40 mA Vs()hi = VB - V(); I() = -40 mA VB = 30 V, V() = 3 V VB = 30 V, V() = VB − 3 V VB = 30 V, V() = VB V() = 0 V VB = 10...30 V, V() = VB/2 VB = 24 V, CL = 100 pF Driver Inputs Ix (x=1...4) Functional input voltage range V(Ix) = 0 to 7.5 V 201 202 203 204 301 302 303 304 305 306 307 501 502 503 504 Vt()lo Vt()hi Vt()hys I() Vt1()lo Vt1()hi Vt1()hys Vt2()hi Vt2()hys Iin() Iin() Voff Von Vhys tp()shut Threshold Voltage lo Threshold Voltage hi Input Hysteresis Input Leakage Current Threshold Voltage lo Threshold Voltage hi Input Hysteresis Threshold Voltage hi Input Hysteresis Input Current Input Current Undervoltage Threshold lo Undervoltage Threshold hi Undervoltage Hysteresis Undervoltage Lockout Delay 35 5 V < V(NEN) < VB 0 V < V(NEN) < 5 V -5 3.0 3.5 3.6 100 20 4.1 Driver enabled without thermal shutdown function for V(NEN) > Vt2()hi 0.1 7.5 0.2 10 0.5 100 400 5 12 0 V < V() < 4.5 V Driver enabled for V(NEN) < Vt1()lo 0.1 -5 0.8 2.4 0.2 5 0.8 2.4 V V V µA V V V V V µA µA V V mV µs Function Input NEN Undervoltage Monitoring iC-HD7 QUAD DIFFERENTIAL LINE DRIVER Rev A5, Page 5/8 ELECTRICAL CHARACTERISTICS Operating Conditions: VB = 4.5...35 V, Tj = -40...125 °C, unless otherwise noted Item No. 601 602 Symbol Parameter Conditions Min. Toff ∆Toff Shutdown Temperature Threshold Temperature Hysteresis NEN = lo NEN = lo 130 Typ. 150 8 Max. 170 °C °C Unit Temperature Monitoring ELECTRICAL CHARACTERISTICS: Diagrams Figure 1: Example of moderate slew rate with unloadad Ox and NOx outputs (VB = 24 V) Figure 2: Example of typical line end signal without termination (VB = 24 V, length of cable 10 m) iC-HD7 QUAD DIFFERENTIAL LINE DRIVER Rev A5, Page 6/8 APPLICATION NOTE Reverse polarity and circuit protection For reverse polarity protection electronic circuitry are usually powered via a diode D in the supply line. Under normal operating conditions, this diode will not affect function of the circuitry when the additional forward voltage drop across the diode is accounted for operating voltage specification. If the supply voltage Vsupply is suddenly reversed, a load capacitor C may be still fully charged. Therefore, the diode D has to be selected to withstand a voltage difference of at least twice the maximum supply voltage. Since the reverse polarity protection diode D prevents discharging of the load capacitor C, especially at low power consumption injected charge through disturbances may in general result in capacitor voltage exceeding maximum ratings, leading to malfunction or destruction of circuitry and associated parts. Thus EMC requirements will afford more external circuitry due to the introduction of a reverse polarity diode. Figure 3 shows the iC-HD7 with the diode D for reverse polarity protection and additional protective devices TS and ZD. Figure 3: Circuit schematic showing protective devices D: reverse polarity protective diode; TS: bidirectional suppressor diode; ZD: supply voltage limiting zener diode For over-voltage protection, the suppressor diode TS absorbs transients on supply line injected externally on the cable. Clamp voltage of the diode TS should be rated slightly above maximum specified supply voltage. Due to capacitive crosstalk between the wires in the cable of the supply line, additional currents may be injected into the circuitry during transients via the driver pins of iC-HD7 connected directly to the cable. These currents can be passed to ground or to VB by the internal ESD diodes of the iC-HD7. Whereas negative current injection will simply be drained off to ground, positive current injection will charge capacitor C further to higher voltages. By introducing an additional Zener diode ZD in parallel to capacitor C, excessive charge can be drained off, thus limiting circuitry supply voltage to a safe value, as shown in fig. 4. Suggested protective devices As stated above, diode D must withstand at least twice the maximum operating voltage. Assuming VBmax specified to be 30V, reverse voltage VR,D of the diode D then should be at least 60 V. Current rating depends on total power consumption of the circuitry, but is usually below 1 amps. Therefore, typical 1 amps rated rectifier diodes like 1N4002 (with VR,D = 100 V) through 1N4007 (with VR,D = 1000 V) or equivalent types (BA157 through BA159) can be used. At VBmax of 30V, neither the suppressor diode TS nor the Zener iC-HD7 QUAD DIFFERENTIAL LINE DRIVER Rev A5, Page 7/8 diode ZD should draw substantial current. Therefore, their breakdown voltage should be chosen to be some volts higher. A 36 V rated suppressor diode with 1.5kW pulse power capability like a 1N6284 or 1.5KE36 the minimum breakdown voltage measured at a test current of 1 mA is stated as 32.4 V. Also, a zener diode like a BZT03C36 rated for 36 V also shows a minimum breakdown voltage of 32.4 V, but measured at test current of 10 mA. Figure 4: Using zener diode ZD to limit circuit supply voltage iC-Haus expressly reserves the right to change its products and/or specifications. An Infoletter gives details as to any amendments and additions made to the relevant current specifications on our internet website www.ichaus.de/infoletter; this letter is generated automatically and shall be sent to registered users by email. Copying – even as an excerpt – is only permitted with iC-Haus approval in writing and precise reference to source. iC-Haus does not warrant the accuracy, completeness or timeliness of the specification on this site and does not assume liability for any errors or omissions in the materials. The data specified is intended solely for the purpose of product description. No representations or warranties, either express or implied, of merchantability, fitness for a particular purpose or of any other nature are made hereunder with respect to information/specification or the products to which information refers and no guarantee with respect to compliance to the intended use is given. In particular, this also applies to the stated possible applications or areas of applications of the product. iC-Haus conveys no patent, copyright, mask work right or other trade mark right to this product. iC-Haus assumes no liability for any patent and/or other trade mark rights of a third party resulting from processing or handling of the product and/or any other use of the product. As a general rule our developments, IPs, principle circuitry and range of Integrated Circuits are suitable and specifically designed for appropriate use in technical applications, such as in devices, systems and any kind of technical equipment, in so far as they do not infringe existing patent rights. In principle the range of use is limitless in a technical sense and refers to the products listed in the inventory of goods compiled for the 2008 and following export trade statistics issued annually by the Bureau of Statistics in Wiesbaden, for example, or to any product in the product catalogue published for the 2007 and following exhibitions in Hanover (Hannover-Messe). We understand suitable application of our published designs to be state-of-the-art technology which can no longer be classed as inventive under the stipulations of patent law. Our explicit application notes are to be treated only as mere examples of the many possible and extremely advantageous uses our products can be put to. iC-HD7 QUAD DIFFERENTIAL LINE DRIVER Rev A5, Page 8/8 ORDERING INFORMATION Type iC-HD7 Package SO16N Order Designation iC-HD7 SO16N For technical support, information about prices and terms of delivery please contact: iC-Haus GmbH Am Kuemmerling 18 D-55294 Bodenheim GERMANY Tel.: +49 (61 35) 92 92-0 Fax: +49 (61 35) 92 92-192 Web: http://www.ichaus.com E-Mail: sales@ichaus.com Appointed local distributors: http://www.ichaus.com/sales_partners