UCT T PROD ACEMEN at E T L E r L P e t E O n R S OB DED pport Ce m/tsc N E Su co MM ECO echnical .intersil. w T NO R Data w r Sheet December 1995, Rev. G u w ct o L or conta -INTERSI 1-888 ® Fast, High Voltage Comparator with Master Slave Flip-Flop The EL2019 offers a new feature previously unavailable in a comparator before—a master/slave edge triggered flip-flop. The comparator output will only change output state after a positive going clock edge is applied. Thus the output can't feed back to the input and cause oscillation. Manufactured with Elantec's proprietary Complementary Bipolar process, this device uses fast PNP and NPN transistors in the signal path. A unique circuit design gives the inputs the ability to handle large common mode and differential mode signals, yet retain high speed and excellent accuracy. Careful design of the front end insures speed and accuracy when operating with a mix of small and large signals. The three-state output stage is designed to be TTL compatible for any power supply combination, yet it draws a constant current and does not generate current glitches. When the output is disabled, the supply current consumption drops by 50%, but the input stage and master slave flip-flop remain active. Ordering Information PART NUMBER EL2019CN EL2019 FN7025 Features • Comparator cannot oscillate • Fast response—5ns data to clock setup, 20ns clock to output • Wide input differential voltage range—24V on ±15V supplies • Wide input common mode voltage range—±12V • Precision input stage—VOS = 1.5mV • Low input bias current—100nA • Low input offset current—30nA • ±4.5V to ±18V supplies • Three-State TTL compatible output • No supply current glitch during switching • 103dB voltage gain (Low input uncertainty ≈ 30µV) • 50% power reduction in shut-down mode • Input and flip-flop remain active in shutdown mode Applications TEMP. RANGE PACKAGE PKG. NO. • Analog to digital converters -40°C to +85°C 8-Pin PDIP MDP0006 • ATE pin receiver • Zero crossing detector Pinout EL2019 (8-PIN PDIP) TOP VIEW 1 • Window detector • “Go/no-go” detector CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures. 1-888-INTERSIL or 321-724-7143 | Intersil (and design) is a registered trademark of Intersil Americas Inc. Copyright © Intersil Americas Inc. 2003. All Rights Reserved. Elantec is a registered trademark of Elantec Semiconductor, Inc. All other trademarks mentioned are the property of their respective owners. EL2019 Absolute Maximum Ratings (TA = 25°C) VS VIN VIN IIN IINS PD Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .±18V Input Voltage+VS to -VS Differential Input Voltage . . . . Limited only by Power Supplies Input Current (Pins 1, 2 or 3). . . . . . . . . . . . . . . . . . . . ±10mA Input Current (Pins 5 or 6). . . . . . . . . . . . . . . . . . . . . . . ±5mA Maximum Power Dissipation . . . . . . . . . . . . . . . . . . . .1.25W IOP IO TA TJ TST Peak Output Current . . . . . . . . . . . . . . . . . . . . . . . . . . . 50mA Continuous Output Current . . . . . . . . . . . . . . . . . . . . . . 25mA Operating Temperature Range . . . . . . . . . . . .-40°C to +85°C Operating Junction Temperature. . . . . . . . . . . . . . . . . . 150°C Storage Temperature . . . . . . . . . . . . . . . . . .-65°C to +150°C The maximum power dissipation depends on package type, ambient temperature and heat sinking. See the Typical Performance curves for more details. CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. IMPORTANT NOTE: All parameters having Min/Max specifications are guaranteed. Typical values are for information purposes only. Unless otherwise noted, all tests are at the specified temperature and are pulsed tests, therefore: TJ = TC = TA DC Electrical Specifications VS = ±15V, unless otherwise specified LIMITS PARAMETER VOS IB IOS DESCRIPTION Input Offset Voltage VCM = 0V, VO Transition Point Input Bias Current VCM = 0V, Pin 2 or 3 Input Offset Current VCM = 0V TEMP MIN 25°C TYP MAX UNITS 1.5 6 mV 8 mV ±400 nA ±600 nA 150 nA 250 nA TMIN, TMAX 25°C ±100 TMIN, TMAX 25°C 30 TMIN, TMAX CMRR Common Mode Rejection Ratio (Note 1) 25°C 75 90 dB PSRR Power Supply Rejection Ratio (Note 2) 25°C 75 95 dB VCM Common Mode Input Range 25°C ±12 ±13 V TMIN, TMAX ±12 VUNCER Input Uncertainty Range VOL Output Voltage Logic Low IOL = 8mA and IOL = 0mA) VOH VODIS1 VODIS2 Output Voltage Logic High VS = ±15V VS = ±15V VS = ±5V VS = ±5V VS = ±5V VOUT Range, Disabled, IOL = -1mA VS = ±15V VS = ±15V VS = ±5V VOUT Range, Disabled, IOL = +1mA VS = ±5V to +15V 2 V 30 25°C -0.05 TMIN, TMAX -0.1 25°C 3.5 TMIN, TMAX 3.5 25°C 2.4 V TMIN 2.4 V TMAX 2.4 V 25°C 4.65 V TMIN, TMAX 4.65 V 25°C All -0.3 0.15 µV/RMS 4.0 0.4 V 0.4 V 4.65 V 4.65 V 3.65 V -1 V EL2019 DC Electrical Specifications VS = ±15V, unless otherwise specified (Continued) LIMITS PARAMETER VINH IIN VINL IS+EN IS+DIS IS-EN IS-DIS DESCRIPTION Clock or CS Inputs Logic High Input Voltage TEMP MIN TYP 25°C 2 V TMIN, TMAX 2 V 25°C Clock or CS Inputs Logic Input Current VIN = 0V and VIN = 5V Positive Supply Current Enabled µA ±300 µA 25°C 0.8 V TMIN, TMAX 0.8 V 13 mA 14 mA 6 mA 7 mA 17 mA 18 mA 8.0 mA 8.0 mA ±300 25°C 8.8 TMIN, TMAX Positive Supply Current Disabled 25°C 4.9 TMIN, TMAX Negative Supply Current Enabled 25°C 14.5 TMIN, TMAX Negative Supply Current Disabled UNITS ±200 TMIN, TMAX Clock or CS Inputs Logic Low Input Voltage MAX 25°C 6.4 TMIN, TMAX NOTES: 1. VCM = +12V to -12V 2. VS = ±5V to ±15V AC Electrical Specifications VS = ±15V, TA = 25°C LIMITS PARAMETER DESCRIPTION MIN TYP MAX UNITS TS Setup Time 5mV Overdrive 12 20 ns TH Hold Time -3 0 ns TOPOUT Clock to Output Delay 20 25 ns TOPMIN Minimum Clock Width 7 TEN Output Three-State Enable Delay 40 70 ns TDIS Output Three-State Disable Delay 150 300 ns 3 ns EL2019 Typical AC Performance Curves 4 Delay Time vs Input Overdrive Delay Time vs Supply Voltage Delay Time vs Temperature Clock to Output Delay vs Load Capacitor Minimum Clock Width vs Temperature Enabled/Disabled Times vs Temperature EL2019 Typical AC Performance Curves (Continued) Input Bias Current vs Differential Input Voltage Input Bias Current vs Common Mode Voltage Supply Current vs Supply Voltage 5 Input Bias Current vs Temperature VO/VI Transfer Characteristics Supply Current vs Temperature EL2019 Typical AC Performance Curves (Continued) VOUT vs Temperature VOH vs Positive Supply Voltage VOH vs Positive Supply Voltage 8-Pin Plastic DIP Maximum Power Dissipation vs Ambient Temperature Clock to Output Delay vs Clock Time Constant Hold Time vs Clock Time Constant 6 Set-up Time vs Clock Time Constant PSRR vs Clock Time Constant Relative VOS Shift vs Clock Time Constant EL2019 Timing Diagram Note: Since the hold time is negative the input is a don't care at the clock time. This ensures that clock noise will not affect the measurement. Block Diagram Function Table INPUTS (TIME N-1) INTERNAL Q (TIME N) NOTES OUTPUT (TIME N) +IN -IN CS + - L H Normal Comparator Operation H - + L L With “D” Flip-Flop L + - + H H H L Normal Comparator Operation With “D” Flip-Flop; Power Down Mode High Z High Z X X X X X X L L L H L Qn-1 Qn-1 Qn-1 Data Retained in Flip-Flop Data Retained in Flip-Flop Data Retained in Flip-Flop Qn-1 Qn-1 Qn-1 X X X X X X H H H Qn-1 Qn-1 Qn-1 Data Retained in Flip-Flop, Output Power Down Mode Data Retained in Flip-Flop, Output Power Down Mode Data Retained in Flip-Flop, Output Power Down Mode High Z High Z High Z CLK L H Application Hints Device Overview The EL2019 is the first comparator of its kind. It is capable of 24V differential signals, yet has excellent accuracy, linearity and voltage gain. The EL2019 has an internal master/slave flip-flop between the input and output. It even has a threestate output feature that reduces the power supply currents 50% when the output is disabled, yet the input stage and 7 latch remain active. This extremely fast and accurate device is built with the proprietary Elantec Complementary Bipolar Process, which is immune to power sequencing and latch up problems. Power Supplies The EL2019 will work with ±5V to ±18V supplies or any combination between (Example +12V and -5V). The supplies should be well bypassed with good high frequency EL2019 capacitors (0.01µF monolithic ceramic recommended) within 1/4 inch of the power supply pins. Good ground plane construction techniques improve stability, and the pin from pin 1 to ground should be short. Front End The EL2019 uses schottky diodes to make a “bullet proof” front end with very low input bias currents, even if the two inputs are tied to very large differential voltages (±24V). The large common mode range (±12V minimum) and differential voltage handling ability (±24V min.) of the device make it useful in ATE applications without the need for an input attenuator with its associated delay. Recovery from Large Overdrives Timing accuracy is excellent for all signals within the common mode range of the device (±12V with ±15V supply). When the common mode range is exceeded the input stage will saturate, input bias currents increase and it may take as much as 200ns for the device to recover to normal operation after the inputs are returned to the common mode range. If signals greater than the common mode range of the device are anticipated, the inputs should be diode clamped to remain within the common mode range of the device, or the supply voltage be raised to encompass the input signal in the common mode range. Input Slew Rate All comparators have input slew rate limitations. The EL2019 operates normally with any input slew rate up to 300V/µs. Input signal slew rates over 300V/µs induce offset voltages of 5mV to 20mV. This induced offset voltage settles out in about 20ns, 20 times faster than previous high voltage comparators. This shows up as an increased set-up time. Master Slave Flip-Flop The built-in Master/Slave Flip-Flop only allows the output to change when a positive edge is received on the clock input. This feature has some major benefits to the user. First, the device cannot oscillate due to feedback from the output to the inputs. Second, the device must make a decision when it receives a clock input, and the difference between deciding on a “0” or a “1” is limited only by the input circuit noise, both internal and external to the EL2019. With low impedance sources and a good layout this uncertainty can be less than 30µV/RMS. Since a 30µV change on the input can cause a 4V change on the output this works out to an effective gain of 103dB, more than adequate for a 16-bit analog to digital converter. The hold time of the EL2019 is worst case 0ns, and typically -3ns. This means that the analog signal is sampled typically 3ns before the clock time and, worst case, concurrent with the clock. The EL2019 is sensitive to a large clock edge rates. More than a 500V/µs edge rate at the clock input will induce VOS 8 shifts, reduce PSRR, and cause the device to operate incorrectly at low temperatures and low supply voltages. A good method to control the clock edge rate is to place a resistor in series and a capacitor to ground in parallel with the clock input. Generally, any time constant 10ns or greater will suffice. Elantec tests the EL2019 with a nominal 20ns time constant, using a series 330Ω resistor and 61pF of capacitance to ground (including strays). All clocks are generated by Schottky TTL and have a 0.25V to 3.5V swing. Output Stage The output stage of the EL2019 is a pair of complementary emitter followers operating as a linear amplifier. This makes the output stage of the EL2019 glitch free, and improves accuracy and stability when operating with small signals. Three-State Output, Power Saving Feature The EL2019 has an output stage which can be put into a high impedance “three-state” mode. When it is in this mode, the input stage and latch remain active, yet the device dissipates only 50% of the power used when the output is active. This has advantages in large ATE systems where there may be 1000 comparators, but only 10% are in use at any one time. The EL2019 will work properly with the chip select input (pin 5) floating, however, good R.F. technique would be to ground this input if it is not used. Due to the power saving feature and linear output stage, the EL2019 does not have a standard TTL three-state output stage. As such one must be careful when using the threestate feature with devices other than other EL2018’s or EL2019’s. When operating from ±15V supplies the threestate feature is compatible with all TTL families, however CMOS families may conflict on high outputs. Since the output stage of the EL2019 turns on faster than it turns off, a 50Ω to 100Ω resistor in series with the output will limit fault currents between devices with minimum impact on logic drive capability. EL2019 Typical Applications USING THE POWER DOWN/ THREE-STATE FEATURE (VIN Range +12V to -12V with VS = ±15V) A WIDE INPUT RANGE WINDOW COMPARATOR The EL2019 makes an excellent comparator in most analog to digital converters, due to its high gain and fast response. Most 2504 based A to D designs can be modified to use the EL2019 simply by using an inverted clock to the EL2019 as shown below. This results in improved performance due to less jitter of the transition voltages. Burn-In Circuit PIN NUMBERS ARE FOR DIP PACKAGES. ALL PACKAGES USE THE SAME SCHEMATIC. 9 EL2019 Equivalent Schematic 10 EL2019 EL2019 Macromodel * Connections: +input * | -input * | | +V * | | | * | | | * | | | * | | | * | | | .subckt M2019 2 3 8 * * Input Stage * i1 8 10 700µA r1 13 4 1K r2 14 4 1K q1 8 3 11 qn q2 8 2 12 qn q3 13 11 10 qp q4 14 12 10 qp i2 11 4 200µA i3 12 4 200µA * * 2nd Stage & Flip Flop * *i4 8 24 700µA i4 8 24 1mA q9 22 6 24 qp q10 18 17 24 qp v1 17 0 2.5V q5 15 14 22 qp q6 16 13 22 qp r3 15 4 1K r4 16 4 1K q7 16 15 18 qp q8 15 16 18 qp i5 8 40 500µA q11 41 17 40 qp q12 42 6 40 qp q13 43 16 41 qp q14 44 15 41 qp q15 44 43 42 qp q16 43 44 42 qp r5 43 4 1K r6 44 4 1K * * Output Stage * i7 8 35 2mA s1 35 20 5 0 sw d2 35 8 ds i6 26 34 5mA s2 34 4 5 0 sw d3 34 26 ds q19 8 20 21 qn 2 q20 4 19 7 qp 2 r8 21 7 60 r7 20 19 4K q17 19 44 26 qn 5 q18 0 43 26 qn 5 11 -V | | | | 4 Cpin | CS | | output | | | 6 5 7 EL2019 q22 20 20 30 qn 5 q23 19 19 30 qn 8 d1 0 19 ds q21 0 17 19 qp * * Power Supply Current * ips 8 4 4mA * * Models * .model qn npn (is=2e-15 bf=400 tf=0.05nS cje=0.3pF cjc=0.2pF ccs=0.2pF) .model qp pnp (is=0.6e-15 bf=60 tf=0.3nS cje=0.5pF cjc=0.5pF ccs=0.4pF) .model ds d(is=2e-12 tt=0.05nS eg=0.62V vj=0.58) .model sw vswitch (von=0.4V voff=2.5V) .ends All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9000 quality systems. Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries. For information regarding Intersil Corporation and its products, see www.intersil.com 12