TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 D D D D D D DW PACKAGE (TOP VIEW) Single-Supply Operation With Rail-to-Rail Inputs VOL = 0.000 V While Sinking 25 mA Wide VCC Range . . . 3.5 V to 15 V SCOUT Supplies up to 100 mA for External Loads Shutdown Mode External 2.5-V Voltage Reference Available 1OUT 1IN – 1IN + VCC – SCOUT SCREF OSC SCIN description 1 16 2 15 3 14 4 13 5 12 6 11 7 10 8 9 VCC + 2OUT 2IN – 2IN + CAP – GND CAP + FB/SD The TLE2662 offers the advantages of JFET-input operational amplifiers and rail-to-rail commonmode input voltage range with the convenience of single-supply operation. By combining a switched-capacitor voltage converter with a dual operational amplifier in a single package, Texas Instruments now gives circuit designers new options for conditioning low-level signals in single-supply systems. The TLE2662 features two low power, high-output drive JFET-input operational amplifiers with a switchedcapacitor building block. Using two external capacitors, the switched-capacitor network can be configured as a voltage inverter, generating a negative supply voltage capable of sourcing up to 100 mA. This supply functions not only as the amplifier negative rail but is also available to drive external circuitry. In this configuration, the amplifier common-mode input voltage range extends from the positive rail to below ground, providing true rail-to-rail inputs from a single supply. Furthermore, the outputs can swing to and below ground while sinking over 25 mA. This feature was previously unavailable in operational amplifier circuits. The TLE2662 operational amplifier section has output stages that can drive 100-Ω loads to 2.5 V from a 5-V rail. With a 10-kΩ load, the output swing extends to 3.5 V and can include the positive rail with a pullup resistor. This operational amplifier offers the high slew rate, wide bandwidth, and high input impedance commonly associated with JFET-input amplifiers, making the TLE2662 operational amplifier section suited for amplifying fast signals without loading the signal source. When not sourcing or sinking current into a load, the amplifier consumes only microamperes of supply current, thereby reducing the drain on and extending the life of the power supply. The TLE2662 features a shutdown pin (FB/SD), which can be used to disable the switched capacitor section. When disabled, the voltage converter block draws less than 150 µA from the power supply. This feature, combined with the operational amplifier’s low quiescent current, makes the TLE2662 a real power saver in the standby mode. The switched-capacitor building block also provides an on-board regulator; with the addition of an external divider, a well-regulated output voltage is easily obtained. Additional filtering can be added to minimize switching noise. The internal oscillator runs at a nominal frequency of 25 kHz. This can be synchronized to an external clock signal or can be varied using an external capacitor. A 2.5-V reference is brought out to SCREF for use with the on-board regulator or external circuitry. The TLE2662 is characterized for operation over the industrial temperature range of – 40°C to 85°C. This device is available in a 16-pin wide-body surface-mount package. AVAILABLE OPTION PACKAGE TA – 40°C to 85°C SMALL OUTLINE (DW) TLE2662IDW The DW package is available taped and reeled. Add the suffix R to the device type (i.e., TLE2662IDWR). Copyright 1994, Texas Instruments Incorporated PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 1 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 functional block diagram 1OUT 1IN – 1IN + VCC – SCOUT SCREF OSC SCIN Amplifier Block 1 2 3 16 15 _ + _ 14 2OUT 2IN – + 4 13 5 12 6 11 SwitchedCapacitor Block 7 8 10 9 ACTUAL DEVICE COMPONENT COUNT AMPLIFIER BLOCK Transistors Resistors Diodes Capacitors 2 VCC + SWITCHEDCAPACITOR BLOCK 42 9 3 2 POST OFFICE BOX 655303 Transistors Resistors Diodes Capacitors 71 44 2 5 • DALLAS, TEXAS 75265 2IN + CAP – GND CAP + FB/SD TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 absolute maximum ratings over operating free-air temperature range (unless otherwise noted)† Supply voltage, SCIN (see Note 1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 V Supply voltage, VCC + (see Note 2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 V Supply voltage, VCC – (see Note 2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 16 V Differential input voltage, VID (see Note 3) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 V Input voltage, VI (any input of amplifier) (see Note 2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VCC ± FB/SD (see Note 1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0 V to SCIN OSC (see Note 1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0 V to SCREF Input current, II (each input of amplifier) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ± 1 mA Output current, IO (each output of amplifier) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ± 80 mA Total current into VCC + . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80 mA Total current out of VCC – . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80 mA Duration of short-circuit current at (or below) TA = 25°C (see Note 4) . . . . . . . . . . . . . . . . . . . . . . . . . unlimited Continuous total dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . See Dissipation Rating Table Junction temperature (see Note 5) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150°C Operating free-air temperature range, TA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 40°C to 85°C Storage temperature range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 65°C to 150°C Lead temperature 1,6 mm (1/16 inch) from case for 10 seconds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 260°C † 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 under “recommended operating conditions” is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. NOTES: 1. Voltage values are with respect to the switched-capacitor block GND. 2. Voltage values, except differential voltages, are with respect to the midpoint between VCC+ and VCC– . 3. Differential voltages are at IN+ with respect to IN –. 4. The output can be shorted to either supply. Temperature and/or supply voltages must be limited to ensure that the maximum dissipation rating is not exceeded. 5. The devices are functional up to the absolute maximum junction temperature. DISSIPATION RATING TABLE PACKAGE TA ≤ 25°C POWER RATING DERATING FACTOR ABOVE TA = 25°C TA = 70°C POWER RATING TA = 85°C POWER RATING DW 1025 mW 8.2 mW/°C 656 mW 533 mW recommended operating conditions Supply voltage, VCC + / SCIN Common mode input voltage, Common-mode voltage VIC VCC ± = ± 5 V VCC ± = ± 15 V Operating free-air temperature, TA Output current at SCOUT, IO POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 MIN MAX 3.5 15 UNIT V – 1.6 4 – 11 13 – 40 85 °C 0 100 mA V 3 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 OPERATIONAL AMPLIFIER SECTION electrical characteristics at specified free-air temperature, VCC ± = ±5 V (unless otherwise noted) TEST CONDITIONS† PARAMETER VIO Input offset voltage αVIO Temperature coefficient of input offset voltage Input offset current IIB Input bias current VICR RS = 50 Ω VIC = 0 0, 0.04 µV/mo 25°C 1 3 Full range – 1.6 to 4 25°C Full range 25°C Full range 25°C 8V VO = ± 2 2.8 V, Large signal differential voltage amplification Large-signal RL = 10 kΩ VO = 0 to 2 V V, RL = 100 Ω VO = 0 to – 2 V V, RL = 100 Ω ri Input resistance Ci Input capacitance zo Open-loop output impedance IO = 0 CMRR Common mode rejection ratio Common-mode RS = 50 Ω,, VIC = VICRmin kSVR Supply voltage rejection ratio (∆VCC ± /∆VIO) Supply-voltage VCC ± = ± 5 V to ± 15 V,, RS = 50 Ω ICC Supply current IL = 0 3.4 nA V V 3.7 V 3.1 2 – 3.4 – 3.9 –3 – 2.5 Full range –2 25°C 15 Full range –2 to 6 3 2.5 nA pA 4 – 1.6 to 4 Full range pA 2 25°C 25°C IL = 20 mA AVD 25°C Common mode input voltage range Common-mode Maximum negative peak output voltage swing mV µV/°C 25°C IL = 2 mA 5 UNIT 6 Full range Maximum positive peak output voltage swing MAX 6.3 Full range IL = 20 mA VOM – TYP 1 Full range IL = 2 mA VOM + MIN Full range Input offset voltage long-term drift (see Note 6) IIO TA‡ 25°C V – 2.7 80 2 25°C 0.75 Full range 0.5 25°C 0.5 Full range 0.25 45 V/mV 3 1012 Ω 25°C 4 pF 25°C 560 Ω 25°C 25°C 65 Full range 65 25°C 75 Full range 65 25°C Full range 82 dB 93 560 dB 620 640 µA † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. ‡ Full range is – 40°C to 85°C. NOTE 6: Typical values are based on the input offset voltage shift observed through 168 hours of operating life test at TA = 150 °C extrapolated to TA = 25 °C using the Arrhenius equation and assuming an activation energy of 0.96 eV. 4 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 operating characteristics at specified free-air temperature, VCC± = ±5 V TEST CONDITIONS† PARAMETER SR Slew rate at unity gain (see Figure 1) Vn Equivalent input noise voltage (see Figure 2) VN(PP) In Peak-to-peak equivalent input noise voltage Equivalent input noise current THD Total harmonic distortion VO(PP) = 2 V,, AVD = 2, B1 Unity gain bandwidth (see Figure 3) Unity-gain ts Settling time BOM Maximum output-swing bandwidth φm Phase margin at unity gain (see Figure 3) TA‡ 25°C MIN TYP 2.2 3.4 Full range 1.7 MAX RL = 10 kΩ kΩ, CL = 100 pF f = 10 Hz, RS = 20 Ω 25°C 59 100 f = 1 kHz, RS = 20 Ω 25°C 43 60 f = 0.1 Hz to 10 Hz 25°C 1.1 f = 1 kHz 25°C 1 f = 10 kHz,, RL = 10 kΩ 25°C 0 025% 0.025% RL = 10 kΩ, CL = 100 pF 25°C 1.8 RL = 100 Ω, CL = 100 pF 25°C 1.3 To 0.1% 25°C 5 To 0.01% 25°C 10 AVD = 1, RL = 10 kΩ, RL = 10 kΩ 25°C 140 CL = 100 pF 25°C 58° RL = 100 Ω, CL = 100 pF 25°C 75° UNIT V/µs nV/√Hz µV fA /√Hz MHz µs kHz † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. ‡ Full range is – 40°C to 85°C. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 5 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 electrical characteristics at specified free-air temperature, VCC ± = ±15 V (unless otherwise noted) TEST CONDITIONS† PARAMETER VIO Input offset voltage αVIO Temperature coefficient of input offset voltage Input offset current IIB Input bias current VICR RS = 50 Ω VIC = 0 0, 4 25°C 0.04 µV/mo 25°C 2 4 Full range – 11 to 13 25°C 13.2 25°C Full range 25°C Full range 25°C IL = 20 mA Large signal differential voltage amplification Large-signal Full range VO = ± 10 V V, RL = 10 kΩ VO = 0 to 8 V V, RL = 600 Ω VO = 0 to – 8 V V, RL = 600 Ω – 12 to 16 nA V V 13.7 13 12.5 nA pA 5 25°C Full range pA 3 – 11 to 13 Common mode input voltage range Common-mode Maximum negative peak output voltage swing mV µV/°C 25°C Maximum positive peak output voltage swing UNIT 6 Full range IL = 2 mA AVD MAX 0.9 Full range IL = 20 mA VOM – TYP 5.3 Full range IL = 2 mA VOM + MIN Full range Input offset voltage long-term drift (see Note 6) IIO TA‡ 25°C V 13.2 12 – 13.2 – 13.7 – 13 – 12.5 V – 13 – 12 25°C 30 Full range 20 25°C 25 Full range 10 25°C 3 Full range 1 230 100 V/mV 25 1012 Ω 25°C 4 pF 25°C 560 Ω ri Input resistance 25°C Ci Input capacitance zo Open-loop output impedance IO = 0 CMRR Common mode rejection ratio Common-mode RS = 50 Ω,, VIC = VICRmin 25°C 72 Full range 65 kSVR Supply voltage rejection ratio (∆VCC ± /∆VIO) Supply-voltage VCC ± = ± 5 V to ± 15 V, RS = 50 Ω 25°C 75 Full range 65 ICC Supply current IL = 0 25°C Full range 90 dB 93 625 dB 690 720 µA † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. ‡ Full range is – 40°C to 85°C. NOTE 6: Typical values are based on the input offset voltage shift observed through 168 hours of operating life test at TA = 150 °C extrapolated to TA = 25 °C using the Arrhenius equation and assuming an activation energy of 0.96 eV. 6 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 operating characteristics at specified free-air temperature, VCC± = ±15 V TEST CONDITIONS† PARAMETER TA‡ 25°C MIN TYP 2.6 3.4 Full range 2.1 MAX UNIT SR Slew rate at unity gain (see Figure 1) RL = 10 kΩ kΩ, CL = 100 pF Vn Equivalent q input noise voltage g (see Figure 2) f = 10 Hz, RS = 20 Ω 25°C 70 100 f = 1 kHz, RS = 20 Ω 25°C 40 60 VN(PP) Peak-to-peak equivalent input noise voltage f = 0.1 Hz to 10 Hz 25°C 1.1 µV In Equivalent input noise current f = 1 kHz 25°C 1.1 fA /√Hz THD Total harmonic distortion VO(PP) = 2 V,, AVD = 2, f = 10 kHz,, RL = 10 kΩ 25°C 0 025% 0.025% B1 Unity gain bandwidth (see Figure 3) Unity-gain RL = 10 kΩ, CL = 100 pF 25°C 2 RL = 600 Ω, CL = 100 pF 25°C 1.5 ts Settling time To 0.1% 25°C 5 To 0.01% 25°C 10 BOM Maximum output-swing bandwidth φm Phase margin at unity gain (see Figure 3) AVD = 1, RL = 10 kΩ, RL = 10 kΩ 25°C 40 CL = 100 pF 25°C 60° RL = 600 Ω, CL = 100 pF 25°C † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. ‡ Full range is – 40°C to 85°C. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 V/µs nV/√Hz MHz µs kHz 70° 7 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 SWITCHED-CAPACITOR SECTION electrical characteristics over recommended supply voltage range and at specified free-air temperature TEST CONDITIONS† PARAMETER Regulated g output voltage, g , SCOUT Input regulation Output regulation RL(SCOUT) = 500 Ω RL(SCOUT) = 500 Ω RL(SCOUT) = 100 Ω to 500 Ω Voltage g loss,, SCIN – SCOUT (see Note 9) SCIN = 7 V,, CIN = COUT = 100-µF tantalum Output resistance SCIN = 7 V, See Note 10 SCIN = 7 V, See Note 7 SCIN = 5 V, See Note 8 SCIN = 7 V to 12 V, See Note 7 SCIN = 5 V to 15 V, See Note 8 SCIN = 7 V, See Note 7 SCIN = 5 V, See Note 8 IO = 10 mA IO = 100 mA ∆IO = 10 mA to 100 mA, Oscillator frequency SCIN = 7 V, V Ireff = 60 µA V SCIN = 5 V, Ireff = 50 µA Maximum switch current IO = 0 SCIN = 15 V TYP MAX – 5.2 –5 – 4.7 UNIT V – 4.25 – 4 – 3.75 5 25 Full range mV 27 10 50 Full range mV 100 0.35 0.55 1.1 1.6 10 15 Ω 15 25 35 kHz 2.5 2.65 Full range Full range 25°C 2.35 Full range 2.25 25°C 2.35 Full range 2.25 25°C SCIN = 3.5 V MIN 25°C Full range Reference voltage, voltage Vreff Supply current, current IS TA‡ Full range 2.75 2.5 2.65 2.75 300 V V V mA 2.5 3.5 3 4.5 mA Supply current in shutdown V(FB/SD) = 0, IO = 0, SCIN = 5 V Full range 100 150 µA † Data applies for the switched-capacitor block only. Amplifier block is not connected. ‡ Full range is – 40°C to 85°C. NOTES: 7. All regulation specifications are for the switched-capacitor section connected as a positive to negative converter/regulator with R1 = 20 kΩ, R2 = 102.5 kΩ, CIN = 10 µF (tantalum), COUT = 100 µF (tantalum) and C1 = 0.002 µF (see Figure 63). 8. All regulation specifications are for the switched-capacitor section connected as a positive to negative converter/regulator with R1 = 23.7 kΩ, R2 = 102.2 kΩ, CIN = 10 µF (tantalum), COUT = 100 µF (tantalum) and C1 = 0.002 µF (see Figure 63). 9. For voltage-loss tests, the switched-capacitor section is connected as a voltage inverter, with SCREF, OSC, and FB/SD unconnected. The voltage losses may be higher in other configurations. 10. Output resistance is defined as the slope of the curve (∆VO vs ∆IO) for output currents of 10 mA to 100 mA. This represents the linear portion of the curve. The incremental slope of the curve is higher at currents less than 10 mA due to the characteristics of the switch transistors. 8 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 AMPLIFIER AND SWITCHED-CAPACITOR SECTIONS CONNECTED electrical characteristics, VCC+ = 5 V, TA = 25°C (see Figure 4) PARAMETER TEST CONDITIONS Maximum positive peak output voltage swing, VOM + Maximum negative peak output voltage swing, VOM – TYP RL = 10 kΩ 3.7 RL = 600 Ω 3.5 RL = 100 Ω 3.1 RL = 10 kΩ – 3.7 RL = 600 Ω – 3.0 RL = 100 Ω – 2.2 CIN = COUT = 100 100-µF µF tantalum, VID = – 100 mV, B h amplifiers lifi Both Voltage loss, SCIN – | SCOUT | (see Note 9) MIN RL = 10 kΩ 0.46 RL = 600 Ω 0.50 MAX UNIT V V V RL = 100 Ω 0.9 NOTES: 9. For voltage-loss tests, the switched-capacitor section is connected as a voltage inverter with SCREF, OSC, and FB/SD unconnected. The voltage losses may be higher in other configurations. supply current (no load), TA = 25°C PARAMETER TEST CONDITIONS Supply current VCC+ = 5 V, VCC+ = 5 V, Supply current in shutdown SCIN = 5 V, SCIN = 5 V, MIN V(FB/SD) = 2.5 V, V(FB/SD) = 0 V, VO = 0 VO = 0 TYP MAX UNIT 3.4 mA 265 µA PARAMETER MEASUREMENT INFORMATION operational amplifier 2 kΩ VCC + VCC + – VO VI – VO + VCC – CL (see Note A) + RL RS = 20 Ω VCC – RS = 20 Ω NOTE A: CL includes fixture capacitance. Figure 1. Slew-Rate Test Circuit POST OFFICE BOX 655303 Figure 2. Noise-Voltage Test Circuit • DALLAS, TEXAS 75265 9 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 PARAMETER MEASUREMENT INFORMATION 10 kΩ VCC + 100 Ω VI – VO + VCC – CL (see Note A) RL NOTE A: CL includes fixture capacitance. Figure 3. Unity-Gain Bandwidth and Phase-Margin Test Circuit amplifier input bias offset current At the picoampere bias-current level typical of the TLE2662, accurate measurement of the amplifier’s bias current becomes difficult. Not only does this measurement require a picoammeter, but test socket leakages can easily exceed the actual device bias currents. To accurately measure these small currents, Texas Instruments uses a two-step process. The socket leakage is measured using picoammeters with bias voltages applied but with no device in the socket. The device is then inserted into the socket and a second test that measures both the socket leakage and the device input bias current is performed. The two measurements are then subtracted algebraically to determine the bias current of the device. RL 1 1OUT VCC + 2 1IN – 2OUT 1IN + 2IN – VCC – 2IN + 3 4 COUT + 0.1 µF SCOUT CAP – SCREF GND 6 7 OSC CAP + SCIN FB/SD 8 Figure 4. Test Circuit 10 POST OFFICE BOX 655303 15 14 0.1 µF RL 13 TLE2662 5 1N4933 16 • DALLAS, TEXAS 75265 12 11 CIN + 10 9 + 2 µF TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS Table of Graphs operational amplifier section FIGURE VIO IIB Input offset voltage Distribution 5 Input bias current vs Free-air temperature 6 IIO VIC Input offset current vs Free-air temperature 6 Common-mode input voltage vs Free-air temperature VOM Maximum peak output voltage vs Output current vs Supply voltage VO(PP) Maximum peak-to-peak output voltage vs Frequency AVD Differential voltage amplification vs Frequency q y vs Free-air temperature 15 16 IOS Short circuit output current Short-circuit vs Time vs Free-air temperature 17 18 zo Output impedance vs Frequency 19 CMRR Common-mode rejection ratio vs Frequency 20 ICC Supply current vs Supply y voltage g vs Free-air temperature 21 22 Pulse response Small signal g Large signal 23, 24 25, 26 Noise voltage (referenced to input) 0.1 to 10 Hz 27 Equivalent input noise voltage vs Frequency 28 Total harmonic distortion vs Frequency 29, 30 B1 Unity gain bandwidth Unity-gain vs Supply y voltage g vs Free-air temperature 31 32 φm Phase margin g vs Supply y voltage g vs Load capacitance vs Free-air temperature 33 34 35 Phase shift vs Frequency 15 Shutdown threshold voltage vs Free-air temperature 36 Supply current vs Input voltage 37 Oscillator frequency vs Free-air temperature 38 Supply current in shutdown vs Input voltage 39 Average supply current vs Output current 40 Output voltage loss vs Input capacitance vs Oscillator frequency 41 42, 43 Regulated output voltage vs Free-air temperature 44 Reference voltage change vs Free-air temperature 45 Voltage loss vs Output current 46 Vn THD 7 8, 9 10,11,12 13, 14 switched-capacitor section ICC fosc VO POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 11 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† OPERATIONAL AMPLIFIER SECTION INPUT BIAS CURRENT AND INPUT OFFSET CURRENT vs FREE-AIR TEMPERATURE DISTRIBUTION OF INPUT OFFSET VOLTAGE 15 10 5 IIB I IO – Input Bias and IIB and IIO Input Offset Currents – nA Percentage of Amplifiers – % 1836 Amplifiers Tested From 1 Wafer Lot VCC ± = ± 15 V TA = 25°C 10 5 0 –4 VCC ± = ± 15 V VIC = 0 10 4 10 3 IIB 10 2 IIO 101 100 –3 –2 –1 0 1 2 3 25 4 45 Figure 5 VOM+ V OM+ – Maximum Positive Peak Output Voltage – V MAXIMUM POSITIVE PEAK OUTPUT VOLTAGE vs OUTPUT CURRENT VIC V IC – Common-Mode Input Voltage – V VCC + + 2 VIC + VCC + VCC – + 4 VCC – + 3 VCC – + 2 – 75 VIC – – 50 – 25 0 25 50 75 TA – Free-Air Temperature – °C 100 20 TA = 25°C 18 16 14 12 VCC ± = ± 15 V 10 8 6 4 2 VCC ± = ± 5 V 0 0 –10 – 20 – 30 Figure 8 † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. POST OFFICE BOX 655303 – 40 IO – Output Current – mA Figure 7 12 85 Figure 6 COMMON-MODE INPUT VOLTAGE vs FREE-AIR TEMPERATURE VCC + + 1 65 TA – Free-Air Temperature – °C VIO – Input Offset Voltage – mV • DALLAS, TEXAS 75265 – 50 – 60 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† OPERATIONAL AMPLIFIER SECTION MAXIMUM PEAK OUTPUT VOLTAGE vs SUPPLY VOLTAGE 20 – 20 TA = 25°C – 18 VVOM OM – Maximum Peak Output Voltage – V VVOM– OM – – Maximum Negative Peak Output Voltage – V MAXIMUM NEGATIVE PEAK OUTPUT VOLTAGE vs OUTPUT CURRENT – 16 – 14 VCC ± = ± 15 V – 12 – 10 –8 –6 –4 VCC ± = ± 5 V –2 0 0 5 10 15 20 25 30 35 15 10 VOM + 5 0 –5 VOM – – 10 – 15 – 20 40 RL = 10 kΩ TA = 25°C 0 2 IO – Output Current – mA Figure 9 10 VOM V OM – Maximum Peak Output Voltage – V VOM V OM – Maximum Peak Output Voltage – V 6 RL = 600 Ω 15 TA = 25°C VOM + 5 0 –5 VOM – – 10 – 15 2 4 6 8 8 10 12 14 16 MAXIMUM PEAK OUTPUT VOLTAGE vs SUPPLY VOLTAGE 20 0 6 Figure 10 MAXIMUM PEAK OUTPUT VOLTAGE vs SUPPLY VOLTAGE – 20 4 |VCC ±| – Supply Voltage – V 10 12 14 16 RL = 100 Ω TA = 25°C 4 VOM + 2 0 –2 VOM – –4 –6 0 |VCC ±| – Supply Voltage – V 2 4 6 |VCC ±| – Supply Voltage – V 8 Figure 12 Figure 11 † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 13 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† OPERATIONAL AMPLIFIER SECTION MAXIMUM PEAK-TO-PEAK OUTPUT VOLTAGE vs FREQUENCY VV)(PP) O(PP) – Maximum Peak-to-Peak Output Voltage – V VO(PP) – Maximum Peak-to-Peak Output Voltage – V VO(PP) MAXIMUM PEAK-TO-PEAK OUTPUT VOLTAGE vs FREQUENCY 10 VCC ± = ± 5 V RL = 10 kΩ TA = 25°C 8 6 4 2 0 10 k 100 k 1M 10 M 30 VCC ± = ± 15 V RL = 10 kΩ TA = 25°C 25 20 15 10 5 0 10 k 100 k 1M f – Frequency – Hz f – Frequency – Hz Figure 13 Figure 14 LARGE-SIGNAL DIFFERENTIAL VOLTAGE AMPLIFICATION and PHASE SHIFT vs FREQUENCY 120 60° Phase Shift ÁÁ ÁÁ 80 80° 100° AVD 60 120° 40 140° 20 0 – 20 0.1 160° VCC ± = ± 15 V RL = 10 kΩ CL = 100 pF TA = 25°C 1 10 180° 100 1k 200° 10 k 100 k 1 M 10 M f – Frequency – Hz Figure 15 † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. 14 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 Phase Shift AVD A VD – Large-Signal Differential Voltage Amplification – dB 100 10 M TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† OPERATIONAL AMPLIFIER SECTION LARGE-SIGNAL DIFFERENTIAL VOLTAGE AMPLIFICATION vs FREE-AIR TEMPERATURE 400 RL = 10 kΩ AVD A VD – Large-Signal Differential Voltage Amplification – V/mV 350 Á Á Á 300 250 VCC ± = ± 15 V 200 150 VCC ± = ± 5 V 100 50 0 – 75 – 50 – 25 0 25 50 75 TA – Free-Air Temperature – °C 100 Figure 16 SHORT-CIRCUIT OUTPUT CURRENT vs TIME SHORT-CIRCUIT OUTPUT CURRENT vs FREE-AIR TEMPERATURE 80 VID = – 100 mV 60 IOS IOS – Short-Circuit Output Current – mA IIOS OS – Short-Circuit Output Current – mA 80 40 VCC ± = ± 15 V TA = 25°C VO = 0 20 0 – 20 – 40 VID = 100 mV – 60 – 80 0 10 20 30 40 50 60 VCC ± = ± 15 V VO = 0 60 VID = – 100 mV 40 20 0 – 20 VID = 100 mV – 40 – 60 – 80 – 75 – 50 – 25 0 25 50 75 100 TA – Free-Air Temperature – °C t – Time – s Figure 17 Figure 18 † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 15 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† OPERATIONAL AMPLIFIER SECTION COMMON-MODE REJECTION RATIO vs FREQUENCY OUTPUT IMPEDANCE vs FREQUENCY 100 35 zzo Ω o – Output Impedance – O 30 CMRR – Common-Mode Rejection Ratio – dB VCC ± = ± 15 V TA = 25°C 25 AVD = 10 20 15 AVD = 100 AVD = 1 10 5 0 100 1k 10 k 100 k 1M TA = 25°C 80 VCC ± = ± 5 V 60 40 20 0 10 10 M 100 1k 10 k 100 k f – Frequency – Hz f – Frequency – Hz Figure 19 Figure 20 SUPPLY CURRENT vs SUPPLY VOLTAGE 1M 10 M SUPPLY CURRENT vs FREE-AIR TEMPERATURE 700 700 VO = 0 No Load 675 675 VO = 0 No Load 650 A IICC CC – Supply Current – µxA µA IICC CC – Supply Current – xA TA = 85°C 625 600 TA = 25°C 575 550 650 VCC ± = ± 15 V 625 600 575 550 VCC ± = ± 5 V TA = – 55°C 525 525 500 0 2 4 6 8 10 12 14 16 500 – 75 – 50 – 25 Figure 22 Figure 21 † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. 16 0 POST OFFICE BOX 655303 25 50 TA – Free-Air Temperature – °C |VCC ±| – Supply Voltage – V • DALLAS, TEXAS 75265 75 100 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† OPERATIONAL AMPLIFIER SECTION VOLTAGE-FOLLOWER SMALL-SIGNAL PULSE RESPONSE 100 100 50 50 VO – Output Voltage – mV VO VO VO – Output Voltage – mV VOLTAGE-FOLLOWER SMALL-SIGNAL PULSE RESPONSE 0 VCC ± = ± 5 V RL = 10 kΩ CL = 100 pF TA = 25°C See Figure 1 – 50 – 100 0 1 2 0 VCC ± = ± 15 V RL = 10 kΩ CL = 100 pF TA = 25°C See Figure 1 – 50 – 100 3 0 1 t – Time – µs t – Time – µs VOLTAGE-FOLLOWER LARGE-SIGNAL PULSE RESPONSE VOLTAGE-FOLLOWER LARGE-SIGNAL PULSE RESPONSE 4 15 VCC ± = ± 5 V RL = 10 kΩ CL = 100 pF TA = 25°C See Figure 1 10 VO – Output Voltage – V VO VO – Output Voltage – V VO 3 Figure 24 Figure 23 3 2 2 1 0 VCC ± = ± 15 V RL = 10 kΩ CL = 100 pF TA = 25°C See Figure 1 5 0 –5 – 10 –1 –2 – 15 0 5 10 15 0 t – Time – µs 10 20 t – Time – µs 30 40 Figure 26 Figure 25 † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 17 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† OPERATIONAL AMPLIFIER SECTION NOISE VOLTAGE (REFERRED TO INPUT) 0.1 TO 10 Hz EQUIVALENT INPUT NOISE VOLTAGE vs FREQUENCY 1 Vn – Equivalent Input Noise Voltage – nV/ Hz VN nVCHz VCC ± = ± 15 V TA = 25°C Noise Voltage – µV uV 0.5 0 – 0.5 100 VDD ± = ± 5 V RS = 20 Ω TA = 25°C See Figure 2 80 60 40 20 0 –1 0 1 2 3 4 5 6 7 8 9 1 10 10 Figure 27 TOTAL HARMONIC DISTORTION vs FREQUENCY 0.6 AVD = 2 VO(PP) = 2 V TA = 25°C THD – Total Harmonic Distortion – % THD – Total Harmonic Distortion – % 0.3 0.2 0.15 VCC ± = ± 5 V 0.1 0.5 0 10 Source Signal 100 1k 10 k 100 k 0.5 AVD = 10 VO(PP) = 2 V TA = 25°C 0.4 0.3 VCC ± = ± 5 V 0.2 Source Signal 0.1 0 10 100 1k f – Frequency – Hz f – Frequency – Hz Figure 29 Figure 30 † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. 18 10 k Figure 28 TOTAL HARMONIC DISTORTION vs FREQUENCY 0.25 1k 100 f – Frequency – Hz t – Time – s POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 10 k 100 k TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† OPERATIONAL AMPLIFIER SECTION UNITY-GAIN BANDWIDTH vs FREE-AIR TEMPERATURE UNITY-GAIN BANDWIDTH vs SUPPLY VOLTAGE 2.5 RL = 10 kΩ CL = 100 pF TA = 25°C See Figure 3 B1 – Unity-Gain Bandwidth – MHz b1 B1 B1 – Unity-Gain Bandwidth – MHz 2.5 2 1.5 2 4 6 8 12 10 14 2 VCC ± = ± 5 V 1.5 RL = 10 kΩ CL = 100 pF See Figure 3 1 – 75 1 0 VCC ± = ± 15 V 16 – 50 – 25 50 75 100 Figure 32 Figure 31 PHASE MARGIN vs SUPPLY VOLTAGE PHASE MARGIN vs LOAD CAPACITANCE 60° 62° RL = 10 kΩ CL = 100 pF TA = 25°C See Figure 3 VCC ± = ± 15 V RL = 10 kΩ TA = 25°C See Figure 3 50° 60° φxx m – Phase Margin 0m φ m – Phase Margin 25 TA – Free-Air Temperature – °C |VCC ±| – Supply Voltage – V 61° 0 59° 58° 40° 30° 20° 57° 10° 56° 55° 0 0° 2 4 6 8 10 12 14 16 0 200 400 600 800 1000 CL – Load Capacitance – pF |VCC ±| – Supply Voltage – V Figure 33 Figure 34 † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 19 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† OPERATIONAL AMPLIFIER SECTION PHASE MARGIN vs FREE-AIR TEMPERATURE 66° RL = 10 kΩ CL = 100 pF See Figure 3 φ m – Phase Margin mm 64° 62° VCC ± = ± 15 V 60° 58° VCC ± = ± 5 V 56° 54° – 75 – 50 0 25 50 75 – 25 TA – Free-Air Temperature – °C 100 Figure 35 SHUTDOWN THRESHOLD VOLTAGE vs FREE-AIR TEMPERATURE SUPPLY CURRENT vs INPUT VOLTAGE 0.6 5 4 V(FB/SD) I CC – Supply Current – mA Shutdown Threshold Voltage – V IO = 0 0.5 0.4 0.3 0.2 2 1 0.1 0 – 50 3 0 25 50 75 – 25 TA – Free-Air Temperature – °C 100 0 0 Figure 36 5 10 VI – Input Voltage – V Figure 37 † Data applies for the amplifier block only; the switched-capacitor block is not supplying VCC – supply. 20 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 15 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† SWITCHED-CAPACITOR SECTION SUPPLY CURRENT IN SHUTDOWN vs INPUT VOLTAGE OSCILLATOR FREQUENCY vs FREE-AIR TEMPERATURE 120 35 Supply Current in Shutdown – µA f osc – Oscillator Frequency – kHz 33 31 29 VCC = 15 V 27 25 VCC = 3.5 V 23 21 19 100 V(FB/SD) = 0 80 60 40 20 17 15 – 75 0 – 50 0 25 50 75 – 25 TA – Free-Air Temperature – °C 100 0 5 10 VI – Input Voltage – V 15 Figure 39 Figure 38 OUTPUT VOLTAGE LOSS vs INPUT CAPACITANCE AVERAGE SUPPLY CURRENT vs OUTPUT CURRENT 1.4 140 TA = 25°C 1.2 IO = 100 mA Output Voltage Loss – V Average Supply Current – mA 120 100 80 60 40 1 0.8 IO = 50 mA 0.6 IO = 10 mA 0.4 Inverter Configuration COUT = 100-µF Tantalum fosc = 25 kHz 0.2 20 0 0 0 20 40 80 60 100 0 10 IO – Output Current – mA Figure 40 20 30 40 50 60 70 80 Ci – Input Capacitance – µF 90 100 Figure 41 † Data applies for the switched-capacitor block only. Amplifier block is not connected. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 21 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† SWITCHED-CAPACITOR SECTION OUTPUT VOLTAGE LOSS vs OSCILLATOR FREQUENCY OUTPUT VOLTAGE LOSS vs OSCILLATOR FREQUENCY 2.5 2.5 Inverter Configuration CIN = 10-µF Tantalum COUT = 100-µF Tantalum 2.25 2 Output Voltage Loss – V 2 Output Voltage Loss – V Inverter Configuration CIN = 100-µF Tantalum COUT= 100-µF Tantalum 2.25 1.75 1.5 IO = 100 mA 1.25 1 IO = 50 mA 0.75 0.5 1.75 1.5 1 0.25 0.25 0 0 10 fosc – Oscillator Frequency – kHz IO = 50 mA 0.75 0.5 IO = 10 mA 1 IO = 100 mA 1.25 IO = 10 mA 1 100 Figure 42 REFERENCE VOLTAGE CHANGE vs FREE-AIR TEMPERATURE 100 – 4.8 Reference Voltage Change – mV VO – Regulated Output Voltage – V – 4.7 – 4.9 –5 – 5.1 –11.6 –11.8 –12 SCREF = 2.5 V 80 TA = 25°C 60 40 20 0 – 20 – 40 –12.2 – 60 –12.4 – 80 75 0 25 50 – 25 TA – Free-Air Temperature – °C 100 – 100 – 50 Figure 44 75 – 25 0 25 50 TA – Free-Air Temperature – °C Figure 45 † Data applies for the switched-capacitor block only. Amplifier block is not connected. 22 100 Figure 43 REGULATED OUTPUT VOLTAGE vs FREE-AIR TEMPERATURE –12.6 – 50 10 fosc – Oscillator Frequency – kHz POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 100 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 TYPICAL CHARACTERISTICS† SWITCHED-CAPACITOR SECTION VOLTAGE LOSS vs OUTPUT CURRENT 2 3.5 V ≤ VCC ≤ 15 V CIN = COUT = 100 µF 1.8 Voltage Loss – V 1.6 1.4 1.2 TA = 85°C 1 0.8 0.6 TA = 25°C 0.4 0.2 0 0 10 20 30 40 50 60 70 Output Current – mA 80 90 100 Figure 46 † Data applies for the switched-capacitor block only. Amplifier block is not connected. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 23 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION amplifier section input characteristics The TLE2662 is specified with a minimum and a maximum input voltage that if exceeded at either input, could cause the device to malfunction. Because of the extremely high input impedance and resulting low bias-current requirements, the TLE2662 operational amplifier section is well suited for low-level signal processing; however, leakage currents on printedcircuit boards and sockets can easily exceed bias-current requirements and cause degradation in system performance. It is a good practice to include guard rings around inputs (see Figure 47). These guards should be driven from a low-impedance source at the same voltage level as the common-mode input. The inputs of any unused amplifiers should be tied to ground to avoid possible oscillation. VI + + VI + VO VO – – VO VI – Figure 47. Use of Guard Rings switched-capacitor section VCC SCREF 2.5 V REF R Drive + CAP + – FB/SD CIN† Q OSC OSC Q R CAP – Drive Drive GND COUT† SCOUT Drive † External capacitors Figure 48. Functional Block Diagram for Switched-Capacitor Block Only 24 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION switched-capacitor section (continued) The TLE2662, with its high-output-drive amplifiers and switched-capacitor voltage converter, readily lends itself to applications like headphone drivers where large signal swing into heavy loads is paramount. Another application is analog-to-digital interfacing when only a single rail is available to the system, but maximization of the ADC dynamic range is key. See Figure 48 for the functional block diagram of the switched-capacitor block. typical application In its most basic configuration, the TLE2662 switched-capacitor section is used as a voltage inverter to provide the negative rail for the amplifiers in a single-supply system. As shown in Figure 49, the positive 5-V supply is connected to both VCC + and SCIN. VCC – is connected to the output of the charge pump, SCOUT. Only three external components (excluding the resistors used with the amplifiers) are necessary: the storage capacitors, CIN and COUT, and a fast-recovery Schottky diode to clamp SCOUT during start up. The diode is necessary because the amplifiers present a load referenced to the positive rail and tends to pull SCOUT above ground, which can cause the device to fail to start up (see pin functions section in APPLICATION INFORMATION). As shown in Figure 50, one amplifier is shown driving a resistive load; the other is interfacing to an analog-to-digital converter (ADC). RL 5V To ADC RF RF Signal From Preamplifier 1 2 3 4 5 Filter 1N4933 COUT + 6 7 8 1OUT VCC + 1IN – 2OUT 1IN + 2IN – VCC – 2IN + SCOUT CAP – SCREF GND OSC CAP + SCIN FB/SD 16 15 RF RIN 14 13 Signal From Transducer 12 CIN 11 + 10 9 Shutdown Figure 49. Switched-Capacitor Block Supplying Negative Rail for Amplifiers POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 25 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION typical application (continued) 5V RF Signal From Preamplifier RF RI Signal From Transducer – + RI Amplifier 1 – + To ADC Amplifier 2 RL Shutdown SCIN SCOUT Voltage Converter FB/SD SCREF Figure 50. Equivalent Schematic: Amplifier 1 Driving Resistive Load, Amplifier 2 Interfacing to an ADC Though simple, this configuration has the inherent disadvantage of having ripple and switching-noise components on SCOUT. These are coupled into the amplifier’s signal path, effectively introducing distortion into the output waveform. The effect is most pronounced when the outputs are driven low, loading the negative rail generated by the charge pump. A first approach to minimizing these effects is to increase the size of COUT using a low-ESR type capacitor (refer to the switched-capacitor selection section under capacitor selection and output ripple). Figures 51 and 52 compare the ripple and noise present at the amplifier output with COUT = 10 µF and COUT = 100 µF, respectively, with the outputs driven low into a 600-Ω load. 26 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION RIPPLE AND SWITCHING NOISE ON AMPLIFIER OUTPUT vs TIME Ripple and Switching Noise on Amplifier Output – mV Ripple and Switching Noise on Amplifier Output – mV typical application (continued) VOL+ 80 VCC+ = 5 V RL = 600 Ω CIN = 100 µF COUT = 10 µF VID = –100 mV VOL+ 60 VOL+ 40 VOL+ 20 VOL VOL– 20 VOL– 40 VOL– 60 VOL– 80 0 10 20 30 40 50 60 70 80 RIPPLE AND SWITCHING NOISE ON AMPLIFIER OUTPUT vs TIME VOL+ 20 VCC+ = 5 V RL = 600 Ω CIN = 100 µF COUT = 100 µF VID = –100 mV VOL+ 15 VOL+ 10 VOL+ 5 VOL VOL– 5 VOL– 10 VOL– 15 VOL– 20 0 90 100 10 20 30 40 50 60 70 80 90 100 t – Time – µs t – Time – µs Figure 51 Figure 52 Additional filtering can be added between SCOUT and VCC – to further reduce ripple and noise. For example, adding the simple low-pass LC filter shown in Figure 53, implemented using a 50-µH inductor and 220-µF capacitor (available in surface mount), results in the reduced levels of ripple and switching noise at the amplifier’s outputs (see Figures 54 and 55). Larger values of L or C can be used for even better attenuation. LH SCOUT VCC 0.1 µF COUT CF + Filter fr = 1 2π LC Figure 53. LC Filter Used to Reduce Ripple and Switching Noise, fr = 1/2π√LC, A = – 40 dB Per Decade POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 27 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION typical application (continued) VOL+ 8 VCC+ = 5 V RL = 600 Ω CIN = 100 µF COUT = 10 µF VOL+ 6 VOL+ 4 VOL+ 2 VOL VOL– 2 VOL– 4 Filter: LF = 50 µH CF = 220 µF See Figure 53 VOL– 6 VOL– 8 0 10 20 30 40 50 60 70 t – Time – µs 80 90 100 RIPPLE AND SWITCHING NOISE ON AMPLIFIER OUTPUT vs TIME Ripple and Switching Noise on Amplifier Output – mV Ripple and Switching Noise on Amplifier Output – mV RIPPLE AND SWITCHING NOISE ON AMPLIFIER OUTPUT vs TIME VOL+ 8 VCC+ = 5 V RL = 600 Ω CIN = 100 µF COUT = 100 µF VOL+ 6 VOL+ 4 VOL+ 2 VOL VOL– 2 VOL– 4 Filter: LF = 50 µH CF = 220 µF See Figure 53 VOL– 6 VOL– 8 0 10 Figure 54 28 20 30 40 50 60 t – Time – µs Figure 55 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 70 80 90 100 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION precision measurement techniques In systems where the amplifier outputs are being sampled by an analog-to-digital converter (ADC), the switched-capacitor network can be temporarily disabled by applying a voltage of less then 0.45 V to FB/SD. This is easily accomplished using any open-collector gate (shown by dashed lines in Figure 49). When disabled, the internal switches are set to dump any remaining charge onto COUT. The voltage at SCOUT decays to zero at a rate dependent on both the size of COUT and loading. During this time, the amplifier’s outputs are free of any switching-induced ripple and noise. Figure 56 shows the relationship of the output voltage decay time to the size of the output storage capacitor when one channel of the amplifier is driving a 100-Ω load to ground. SCOUT rises again when the external gate is turned off (see Figure 57). OFF-STATE VOLTAGE DECAY AT OUTPUT vs TIME TURN-ON VOLTAGE RISE AT OUTPUT vs TIME 6 VCC+ = 5 V VCC – = SCOUT CIN = 100 µF RL = 100 Ω VID = – 100 mV 4 Turn-On Voltage Rise at Output – V Off-State Voltage Decay at Output – V 6 2 COUT = 22 µF 0 COUT = 100 µF –2 COUT = 220 µF –4 VCC+ = 5 V VCC – = SCOUT CIN = 100 µF RL = 100 Ω VID = – 100 mV 4 2 0 COUT = 100 µF –2 COUT = 220 µF –4 COUT = 22 µF –6 –6 0 10 20 30 40 50 t – Time – ms 60 70 80 0 10 Figure 56 20 30 40 50 t – Time – ms 60 70 80 Figure 57 The amplifier’s negative input common-mode voltage limit (VICR –) is specified as an offset from the negative rail. Care should be taken to ensure that the input signal does not violate this limit as SCOUT decays. The negative output voltage swing is similarly affected by the gradual loss of the negative rail. This application takes advantage of the otherwise unused SCREF output of the switched-capacitor block to bias one amplifier to 2.5 V. This is especially useful when the amplifier is followed by an ADC, keeping the signal centered in the middle of the converter dynamic range. Other biasing methods may be necessary in precision systems. In Figure 58, SCREF , R1, and R2 are used to generate a feedback voltage to the TLE2662 error amplifier. This voltage, fed into FB/SD, is used to regulate the voltage at SCOUT. When used this way, there is higher voltage loss ( SCIN – |SCOUT| ) associated with the regulation. For example, the inverter generates an unregulated voltage of approximately – 4.5 V from a positive 5-V source; it can achieve a regulated output voltage of only about – 3.5 V. Though this reduces the amplifier input and output dynamic range, both VICR – and VOL still extend to below ground. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 29 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION precision measurement techniques (continued) RL 5V To ADC RF RI 1 2 COUT 3 1OUT VCC + 1IN – 2OUT 1IN + 2IN – VCC – 2IN + 16 15 RF RI 14 + 4 + C1 R2 5 R1 SCOUT 6 SCREF 7 1N4933 8 CAP– GND OSC CAP+ SCIN FB/SD 13 12 CIN 11 + 10 9 Restart R2 + R1 ǒ | SCOUT | SCREF 40 mV 2 * Ǔ )1 R3 Shutdown R4 Where: SCREF = 2.5 V Nominal Figure 58. Voltage Inverter With Regulated Output The reference voltage, though being used as part of the regulation circuitry, is still available for other uses if total current drawn from it is limited to under 60 µA. The shutdown feature also remains available, though a restart pulse may be necessary to start the switched-capacitor if the voltage on COUT is not fully discharged. This restart pulse is isolated from the feedback loop using a blocking diode in the regulation section. The circuit designer should be aware that the TLE2662 amplifier and switched-capacitor sections are tested and specified separately. Performance may differ from that shown in the typical characteristics section when used together. This is evident, for example, in the dependence of VICR – and VOL on VCC –. The impact of supplying the amplifier negative rail using the switched-capacitor block in each design should be considered and carefully evaluated. The more esoteric features of the switched-capacitor building block, including external synchronization of the internal oscillator and power dissipation considerations, are covered in detail in the following section. 30 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION switched-capacitor function A review of a basic switched-capacitor building block is helpful in understanding the operation of the TLE2662. When the switch shown in Figure 59 is in the left position, capacitor C1 charges to the voltage at V1. The total charge on C1 is q1 = C1V1. When the switch is moved to the right, C1 is discharged to the voltage at V2. After this discharge time, the charge on C1 is q2 = C1V2. The charge has been transferred from the source V1 to the output V2. The amount of charge transferred is as shown in equation 1. ∆q = q1 – q2 = C1(V1 – V2) (1) If the switch is cycled f times per second, the charge transfer per unit time (i.e., current) is shown in equation 2. I = f x ∆q = f x C1(V1 – V2) (2) To obtain an equivalent resistance for a switched-capacitor network, this equation can be rewritten in terms of voltage and impedance equivalence as shown in equation 3. I + V1(1ń*fC1)V2 + V1R * V2 (3) EQUIV V1 V2 f C1 RL C2 Figure 59. Switched-Capacitor Block A new variable, REQUIV, is defined as REQUIV = 1 ÷ fC1. The equivalent circuit for the switched-capacitor network is as shown in Figure 60. The TLE2662 has the same switching action as the basic switched-capacitor voltage converter. Even though this simplification does not include finite switch-on resistance and output-voltage ripple, it provides an insight into how the device operates. These simplified circuits explain voltage loss as a function of oscillator frequency (see Figure 43). As oscillator frequency is decreased, the output impedance is eventually dominated by the 1/fC1 term and voltage losses rise. Voltage losses also rise as oscillator frequency increases. This is caused by internal switching losses that occur due to some finite charge being lost on each switching cycle. This charge loss per-unit-cycle, when multiplied by the switching frequency, becomes a current loss. At high frequency, this loss becomes significant and voltage losses again rise. The oscillator of the TLE2662 switched-capacitor section is designed to run in the frequency band where voltage losses are at a minimum. REQUIV V1 REQUIV = V2 1 fC1 C2 RL Figure 60. Switched-Capacitor Equivalent Circuit POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 31 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION pin functions (see functional block diagram – converter) Supply voltage (SCIN) alternately charges CIN to the input voltage when CIN is switched in parallel with the input supply, and then transfers charge to COUT when CIN is switched in parallel with COUT. Switching occurs at the oscillator frequency. During the time that CIN is charging, the peak supply current is approximately 2.2 times the output current. During the time that CIN is delivering a charge to COUT, the supply current drops to approximately 0.2 times the output current. An input supply bypass capacitor supplies part of the peak input current drawn by the TLE2662 switched-capacitor section and averages out the current drawn from the supply. A minimum input supply bypass capacitor of 2 µF, preferably tantalum or some other low-ESR type, is recommended. A larger capacitor is desirable in some cases. An example is when the actual input supply is connected to the TLE2662 through long leads or when the pulse currents drawn by the TLE2662 might affect other circuits through supply coupling. In addition to being the output pin, SCOUT is tied to the substrate of the device. Special care must be taken in TLE2662 circuits to avoid making SCOUT positive with respect to any of the other pins. For circuits with the output load connected from VCC + to SCOUT or from some external positive supply voltage to SCOUT, an external Schottky diode must be added (see Figure 61). This diode prevents SCOUT from being pulled above the GND during start up. A fast-recovery diode such as IN4933 with low forward voltage (Vf ≈ 0.2 V) can be used. 1 1OUT VCC + 1IN – 2OUT 1IN + 2IN – VCC – 2IN + 2 3 4 5 SCOUT IN4933 COUT + SCOUT CAP – SCREF GND 6 7 OSC CAP + SCIN FB/SD 8 Load 16 15 14 13 12 11 CIN + 10 9 VCC+ or External Supply Voltage Figure 61. Circuit With Load Connected From VCC to SCOUT The voltage reference (SCREF) output provides a 2.5-V reference point for use in TLE2662-based regulator circuits. The temperature coefficient (TC) of the reference voltage has been adjusted so that the TC of the regulated output voltage is near zero. As seen in the typical performance curves, this requires the reference output to have a positive TC. This nonzero drift is necessary to offset a drift term inherent in the internal reference divider and comparator network tied to the feedback pin. The overall result of these drift terms is a regulated output that has a slight positive TC at output voltages below 5 V and a slight negative TC at output voltages above 5 V. For regulator-feedback networks, reference output current should be limited to approximately 60 µA. SCREF draws approximately 100 µA when shorted to ground and does not affect the internal reference/regulator. This pin can also be used as a pullup for TLE2662 circuits that require synchronization. 32 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION pin functions (continued) CAP+ is the positive side of input capacitor (CIN) and is alternately driven between VCC and ground. When driven to VCC, CAP+ sources current from VCC. When driven to ground, CAP+ sinks current to ground. CAP – is the negative side of the input capacitor and is driven alternately between ground and SCOUT. When driven to ground, CAP– sinks current to ground. When driven to SCOUT, CAP– sources current from COUT. In all cases, current flow in the switches is unidirectional as should be expected when using bipolar switches. OSC can be used to raise or lower the oscillator frequency or to synchronize the device to an external clock. Internally, OSC is connected to the oscillator timing capacitor (Ct ≈ 150 pF), which is alternately charged and discharged by current sources of ±7 µA, so that the duty cycle is approximately 50%. The TLE2662 switched-capacitor section oscillator is designed to run in the frequency band where switching losses are minimized. However, the frequency can be raised, lowered, or synchronized to an external system clock if necessary. The frequency can be increased by adding an external capacitor (C2 in Figure 62) in the range of 5 pF – 20 pF from CAP+ to OSC. This capacitor couples a charge into Ct at the switch transitions. This shortens the charge and discharge time and raises the oscillator frequency. Synchronization can be accomplished by adding an external pullup resistor from OSC to SCREF . A 20-kΩ pullup resistor is recommended. An open-collector gate or an npn transistor can then be used to drive OSC at the external clock frequency as shown in Figure 62. The frequency can be lowered by adding an external capacitor (C1 in Figure 62) from OSC to ground. This increases the charge and discharge times, which lowers the oscillator frequency. 1 1OUT VCC + 1IN – 2OUT 1IN + 2IN – VCC – 2IN + 2 3 4 COUT 5 C1 SCOUT CAP – SCREF GND + 6 7 C2 SCIN OSC CAP + SCIN FB/SD 8 16 15 14 13 12 CIN 11 + 10 9 Figure 62. External Clock System The feedback/shutdown (FB/SD) pin has two functions. Pulling FB/SD below the shutdown threshold ( ≈ 0.45 V) puts the device into shutdown. In shutdown, the reference/regulator is turned off and switching stops. The switches are set such that both CIN and COUT are discharged through the output load. Quiescent current in shutdown drops to approximately 100 µA . Any open-collector gate can be used to put the TLE2662 into shutdown. For normal (unregulated) operation, the device restarts when the external gate is shut off. In TLE2662 circuits that use the regulation feature, the external resistor divider can provide enough pulldown to keep the device in shutdown until the output capacitor (COUT) has fully discharged. For most applications POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 33 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION where the TLE2662 is run intermittently, this does not present a problem because the discharge time of the output capacitor is short compared to the off time of the device. In applications where the device has to start-up before the output capacitor (COUT) has fully discharged, a restart pulse must be applied to FB/SD of the TLE2662. Using the circuit shown in Figure 63, the restart signal can be either a pulse (tp > 100 µs) or a logic high. Diode coupling the restart signal into FB/SD allows the output voltage to rise and regulate without overshoot. The resistor divider R3/R4 shown in Figure 63 should be chosen to provide a signal level at FB/SD of 0.7 V – 1.1 V. FB/SD is also the inverting input of the TLE2662 switched-capacitor section error amplifier, and as such can be used to obtain a regulated output voltage. COUT 100 µF Tantalum + 1 1OUT VCC + 1IN – 2OUT 1IN + 2IN – VCC – 2IN + 2 C1 + 3 4 SCOUT R2 5 SCOUT R1 CAP – 6 SCREF GND 7 + R1 ǒ 2.2 µF | SCOUT | SCREF 40 mV 2 * CAP + SCIN FB/SD 8 SCIN R2 OSC Ǔ + 16 15 14 13 12 11 + CIN 10 µF Tantalum 10 9 R3 R4 )1 Shutdown Where: SCREF = 2.5 V Nominal Restart Figure 63. Basic Regulation Configuration regulation The error amplifier of the TLE2662 switched-capacitor section drives the npn switch to control the voltage across the input capacitor (CIN), which determines the output voltage. When the reference and error amplifier of the TLE2662 is used, an external resistive divider is all that is needed to set the regulated output voltage. Figure 63 shows the basic regulator configuration and the formula for calculating the appropriate resistor values. R1 should be 20 kΩ or greater because the reference current is limited to ± 100 µA. R2 should be in the range of 100 kΩ to 300 kΩ. Frequency compensation is accomplished by adjusting the ratio of CIN to COUT. For best results, this ratio should be approximately 1 to 10. Capacitor C1, required for good load regulation, should be 0.002 µF for all output voltages. 34 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION regulation (continued) The functional block diagram shows that the maximum regulated output voltage is limited by the supply voltage. For the basic configuration, SCOUT referenced to GND of the TLE2662 must be less than the total of the supply voltage minus the voltage loss due to the switches. The voltage loss versus output current due to the switches can be found in the typical performance curves. capacitor selection While the exact values of CIN and COUT are noncritical, good-quality low-ESR capacitors such as solid tantalum are necessary to minimize voltage losses at high currents. For CIN, the effect of the equivalent series resistance (ESR) of the capacitor is multiplied by four, since switch currents are approximately two times higher than output current. Losses occur on both the charge and discharge cycle, which means that a capacitor with 1 Ω of ESR for CIN has the same effect as increasing the output impedance of the switched-capacitor section by 4 Ω. This represents a significant increase in the voltage losses. COUT is alternately charged and discharged at a current approximately equal to the output current. The ESR of the capacitor causes a step function to occur in the output ripple at the switch transitions. This step function degrades the output regulation for changes in output load current and should be avoided. A technique used is to parallel a smaller tantalum capacitor with a large aluminum electrolytic capacitor to gain both low ESR and reasonable cost. output ripple The peak-to-peak output ripple is determined by the output capacitor and the output current values. Peak-to-peak output ripple is approximated as shown in equation 4: DV + 2 IfCO (4) O where: ∆V = peak-to-peak ripple fOSC = oscillator frequency For output capacitors with significant ESR, a second term must be added to account for the voltage step at the switch transitions. This step is approximately equal to equation 5: ǒ Ǔǒ 2I O ESR of C Ǔ (5) O power dissipation (switched-capacitor section only) The power dissipation of any TLE2662 circuit must be limited so that the junction temperature of the device does not exceed the maximum junction temperature ratings. The total power dissipation is calculated from two components, the power loss due to voltage drops in the switches, and the power loss due to drive current losses. The total power dissipated by the TLE2662 is calculated as shown in equation 6: P [ (VCC – Ť Ť V O ) I O ) (VCC) (IO) (0.2) (6) where both VCC and SCOUT refer to GND. The power dissipation is equivalent to that of a linear regulator. Due to limitations of the DW package, steps must be taken to dissipate power externally for large input or output differentials. This is accomplished by placing a resistor in series with CIN as shown in Figure 64. A portion of the input voltage is dropped across this resistor without affecting the output regulation. Since switch current is approximately 2.2 times the output current and the resistor causes a voltage drop when CIN is both charging and discharging, the resistor chosen is as shown in equation 7. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 35 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION power dissipation (continued) X + VXń(4.4 IO) X [ VCC– R where: V (7) ƪ (TLE2662 voltage loss) (1.3) ) Ť Ťƫ V O and IOUT = maximum required output current. The factor of 1.3 allows some operating margin for the TLE2662. When using a 12-V to – 5-V converter at 100-mA output current, calculate the power dissipation without an external resistor as shown in equation 8. + (12 V * | * 5 V | ) (100 mA) ) (12 V) (100 mA) (0.2) P + 700 mW ) 240 mW + 940 mW P 1 COUT + 1OUT VCC + 1IN – 2OUT 1IN + 2IN – VCC – 2IN + 2 C1 3 + 4 SCOUT R2 5 R1 SCOUT CAP – SCREF GND 6 7 OSC CAP + (8) 16 15 14 13 12 11 CIN + 10 Rx 8 SCIN FB/SD 9 + SCIN Figure 64. Power-Dissipation-Limiting Resistor in Series With CIN At θJA of 130°C/W for a commercial plastic device, a junction temperature rise of 122°C is seen. The device exceeds the maximum junction temperature at an ambient temperature of 25°C. To calculate the power dissipation with an external-resistor (RX), determine how much voltage can be dropped across RX. The maximum voltage loss of the TLE2662 in the standard regulator configuration at 100 mA output current is 1.6 V (see equation 9). X + 12 V * ƪ(1.6 V) (1.3) ) Ť – 5 V Ť ƫ + 4.9 V X + 4.9 Vń(4.4) (100 mA) + 11 W V and R 36 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 (9) TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION power dissipation (continued) The resistor reduces the power dissipated by the TLE2662 by (4.9 V) (100 mA) = 490 mW. The total power dissipated by the TLE2662 is equal to (940 mW – 490 mW) = 450 mW. The junction temperature rise is 58°C. Although commercial devices are functional up to a junction temperature of 125°C, the specifications are tested to a junction temperature of 100°C. In this example, this means limiting the ambient temperature to 42°C. To allow higher ambient temperatures, the thermal resistance numbers for the TLE2662 packages represent worst-case numbers with no heat sinking and still air. Small clip-on heat sinks can be used to lower the thermal resistance of the TLE2662 package. Airflow in some systems helps to lower the thermal resistance. Wide PC board traces from the TLE2662 leads helps to remove heat from the device. This is especially true for plastic packages. basic voltage inverter The switched-capacitor block is connected as a basic voltage inverter with regulation as shown in Figure 65. The magnitude of SCIN must exceed that of the desired SCOUT to accommodate voltage losses due to switching and regulation. Losses of 1 V to 2 V are typical. 1 100 µF + 1OUT VCC + 1IN – 2OUT 1IN + 2IN – VCC – 2IN + 16 2 0.002 µF 15 3 + 14 4 SCOUT R2 13 5 R1 SCOUT CAP – SCREF GND 12 6 11 + 7 CAP + SCIN FB/SD 10 8 SCIN 2 µF R2 OSC + R1 ǒ + | SCOUT | SCREF 40 mV 2 * Ǔ ) 1 + R1 ǒ | SCOUT 1.121 V | 10 µF 9 Ǔ )1 Figure 65. Basic Voltage Inverter/Regulator POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 37 TLE2662 DUAL µPOWER JFET-INPUT OPERATIONAL AMPLIFIER WITH SWITCHED-CAPACITOR VOLTAGE CONVERTER SLOS118B – DECEMBER 1992 – REVISED AUGUST 1994 APPLICATION INFORMATION positive voltage doubler In this configuration (see Figure 66), the voltage converter is configured as a positive voltage doubler providing a higher positive rail, approximately 9 V for the amplifiers or other external circuitry. Filtering (not shown) of the output of the doubler may be necessary. Output Signal 1 1OUT VCC + 1IN – 2OUT 2 3 1IN + 2IN – VCC – 2IN + 4 5 SCOUT CAP – SCREF GND 6 7 OSC CAP + SCIN FB/SD 8 5V 16 15 RF R RIN 14 Input Signal 13 12 R 11 10 10 µF 9 + VO 2 µF + 1N4001 1N4001 + 100 µF Figure 66. Voltage Converter Configured as Positive Doubler 38 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 PACKAGE OPTION ADDENDUM www.ti.com 30-Mar-2005 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty TLE2662IDW OBSOLETE SOIC DW 16 TBD Call TI Call TI TLE2662IDWR OBSOLETE SOIC DW 16 TBD Call TI Call TI Lead/Ball Finish MSL Peak Temp (3) (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS) or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. 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