MIC86 Teeny Ultra Low Power Op Amp General Description The MIC86 is a rail-to-rail output, input common-mode to ground, operational amplifier in Teeny SC7 packaging. The MIC86 provides 4kHz gain-bandwidth product while consuming an incredibly low 4.6µA supply current. The SC7 packaging achieves significant board space savings over devices packaged in SOT-2 or MSOP-8 packaging. The SC7 occupies approximately half the board area of a SOT-2 package. Features Teeny SC7 packaging 4kHz gain-bandwidth product 65kHz, db bandwidth 4.6µA supply current Rail-to-Rail output Ground sensing at input (common mode to GND) Drives large capactive loads (pf) Unity gain stable Applications Portable equipment PDAs Pagers Cordless Phones Consumer Electronics Ordering Information Part Number Ambient Package Standard Marking Pb-Free Marking* Temp. Range MIC86BC5 A MIC86YC5 A 4ºC to +85ºC SC-7-5 * Underbar marking may not be to scale. Pin Configuration Functional Pinout IN V 2 A IN+ Part Identification IN V 2 IN+ 4 5 OUT V+ 4 5 OUT V+ SC-7 Teeny is a trademark of 28 Fortune Drive San Jose, CA 95 USA tel + (48) 944-8 fax + (48) 474- http://www.micrel.com February 26 M9999-2276
Absolute Maximum Ratings (Note ) Supply Voltage (V V+ V )...+6.V Differentail Input Voltage ( V IN+ V IN ), Note 4...+6.V Input Voltage (V IN+ V IN )...V + +.V, V.V Lead Temperature (soldering, 5 sec.)... 26 C Output Short Circuit Current Duration...Indefinite Storage Temperature (T S )... 5 C ESD Rating, Note Operating Ratings (Note 2) Supply Voltage (V+ V )... +2.4V to +5.25V Ambient Temperature Range... 4 C to +85 C Package Thermal Resistance... 45 C/W Electrical Characteristics V+ = +2.7V, V = V, V CM = V+/2; R L = 5kΩ to V+/2; T A = 25 C, unless otherwise noted. Bold values indicate 4 C T A +85 C. Symbol Parameter Condition Min Typ Max Units V OS Input Offset Voltage Note 5 2 mv Input Offset Voltage Temp Coefficient 5 µv/ C I B Input Bias Current 2 pa I OS Input Offset Current pa V CM Input Voltage Range CMRR > 6dB.8 V CMRR Common-Mode Rejection Ratio < V CM <.5V 45 77 db PSRR Power Supply Rejection Ratio Supply voltage change of V 5 8 db A VOL Large-Signal Voltage Gain R L = k, V OUT 2V peak to peak 6 74 db R L = 5k, V OUT 2V peak to peak 7 8 db V OUT Maximum Output Voltage Swing R L = 5k V+ 2mV V+.7mV V V OUT Minimum Output Voltage Swing R L = 5k V +.2mV V + 2mV V GBW Gain-Bandwidth Product R L = 2kΩ,, V OUT = 5 khz BW db Bandwidth A V =,, 5 khz SR Slew Rate A V =,,.2 V/µs I SC Short-Circuit Output Current Source 6 ma Sink 5 ma I S Supply Current No Load 4.2 9 µa V+= +5V, V = V, V CM = V+/2; R L = 5kΩ to V+/2; T A = 25 C, unless otherwise noted. Bold values indicate 4 C T A +85 C. V OS Input Offset Voltage Note 5 2 mv Input Offset Voltage Temp Coefficient 5 µv/ C I B Input Bias Current 2 pa I OS Input Offset Current pa V CM Input Voltage Range CMRR > 6dB 4.2 V CMRR Common-Mode Rejection Ratio < V CM <.5V 6 8 db PSRR Power Supply Rejection Ratio Supply voltage change of V 45 85 db A VOL Large-Signal Voltage Gain R L = k, V OUT 4.V peak to peak 6 76 db R L = 5k, V OUT 4.V peak to peak 68 8 db V OUT Maximum Output Voltage Swing R L = 5k V+ 2mV V+.7mV V V OUT Minimum Output Voltage Swing R L = 5k V +.7mV V + 2mV V GBW Gain-Bandwidth Product R L = 2kΩ,, V OUT = 4 khz BW db Bandwidth A V =,, 65 khz M9999-2276 2 February 26
Symbol Parameter Condition Min Typ Max Units SR Slew Rate A V =,,.2 V/µs I SC Short-Circuit Output Current Source 24 ma Sink 24 ma I S Supply Current No Load 4.6 9 µa Note. Note 2. Note. Note 4. Note 5. Exceeding the absolute maximum rating may damage the device. The device is not guaranteed to function outside its operating rating. Devices are ESD sensitive. Handling precautions recommended. Human body model,.5k in series with pf. Pin 4 is ESD sensetive Exceeding the maximum differential input voltage will damage the input stage and degrade performance (in particular, input bias current is likely to increase. The offset voltage distribution is centered around V. The typical offset number shown, is equal to the standard deviation of the voltage offset distribution. February 26 M9999-2276
Test Circuits Test Circuit. A V = Test Circuit 2:A V = 2 Test Circuit. A V = Test Circuit 4. A V = V+ µf µf Input BNC 5Ω µf.µf k 48k k MIC86 7k BNC Output 5Ω.µF All resistors: % metal film µf V µf Test Circuit 5. Positive Power Supply Rejection Ratio Measurement M9999-2276 4 February 26
DC Performance Characteristics 5 4 Output Voltage vs. Output Current Sourcing 5 Sinking 4 Output Voltage vs. Output Current 25 C Short Circuit Current vs. Supply Voltage Sourcing 25-4 C 2 85 C 5 25 C 2-4 C 85 C 25 C -5 - -5-2 -25 - -5-4 CURRENT (ma) 2-4 C 5 5 2 25 CURRENT (ma) 5 85 C.8.2.4.6.8 2 2.2 2.4 SUPPLY VOLTAGE (±V) Short Circuit Current vs. Supply Voltage Sinking 25-4 C. Offset Voltage vs. Common-Mode Voltage V+ = 2.7V 85 C Offset Voltage vs. Common-Mode Voltage. V+ = 5V 85 C 2 25 C.9.9 25 C 5 5 85 C.8.7.6 25 C 4 C.8.7.6 4 C.9...5.7.9 2. 2. 2.5 SUPPLY VOLTAGE (±V).5.5.5 2 2.5 COMMON-MODE VOLTAGE (V).5.5.5 2 2.5.5 4 4.5 5 COMMON-MODE VOLTAGE (V) 9 8 7 6 5 4 2 Offset Voltage vs. Supply Voltage 85 C 25 C -4 C.9...5.7.9 2. 2. 2.5 SUPPLY VOLTAGE (V) 8 6 4 2 Open Loop Gain vs. Resistive Load V+ = 5V V+ = 2.7V. RESISTIVE LOAD (kω) 7 6 5 4 2 Supply Current vs. Temperature 5V 2.7V -4-2 2 4 6 8 TEMPERATURE ( C) - -2 - Offset Voltage vs. Temperature 5V 25 2 5 Short Circuit Current vs. Temperature Sourcing 5V -5 - -5 Short Circuit Current vs. Temperature Sinking 2.7V -4-5 2.7V -6-4 -2 2 4 6 8 TEMPERATURE ( C) 5 2.7V -4-2 2 4 6 8 TEMPERATURE ( C) -2-25 5V - -4-2 2 4 6 8 TEMPERATURE ( C) February 26 5 M9999-2276
AC Perfomance Characteristics 425 75 25 275 75 25 75 Gain Bandwidth vs. Capacitive Load 5V 2.7V 25 CAPACITIVE LOAD (pf) 9 8 7 6 5 4 2 CMRR vs. Frequency V+= 5V k k k M 9 8 7 6 5 4 2 - V+ = 5V PSRR vs. Frequency k k k M 8 6 4 2 CMRR vs. Frequency V+ = 2.7V k k k M 8 6 4 2 PSRR vs. Frequency V+ = 2.7V -2 k k k M 5 4 2 - -2 - -4-5 Gain Bandwidth and Phase Margin Av = V- =.5V C L = 2pF R F = 2kΩ k k k M 8 5 9 45-45 -9-5 -8-5 4 2 - -2 - -4-5 Gain Bandwidth and Phase Margin Av = V = 2.5V R F = 2kΩ 8 5 9 45-45 -9-5 -8 k k k M - 5 4 2 - -2 - -4-5 Unity Gain Frequency Response Av = V = 2.5V k k k M 8 5 9 45-45 -9-5 -8-5 4 2 - -2 - -4-5 Unity Gain Frequency Response Av = V =.5V R L = MkΩ k k k M 8 5 9 45-45 -9-5 -8 - Gain Frequency Response 5 4 2 - Av = 2-2 V- =.5V - -4 R F = 2kΩ -5 k k k M 8 5 9 45-45 -9-5 -8 - Gain Bandwidth and Phase Margin 5 4 8 5 2 9 45 - Av = 2-45 -2-9 V- = 2.5V - -5-4 R F = 2kΩ -8-5 - k k k M M9999-2276 6 February 26
Close-loop Unity Gain Frequency Response 8 5 2 9 6 A V = µf.µf.µf pf pf pf RF V+ V C L FET Probe - -6 k k k M M February 26 7 M9999-2276
Functional Characteristics Test Circuit : A V = Test Circuit : A V = 5mV/div Test Circuit 4: A V = - Test Circuit 4: A V = - 5mV/div A V = - R L = 5kΩ R F = 2kΩ 5mV/div 5mV/div 5mV/div A V = V- = -.5V 5mV/div 5mV/div A V = TIME µs/div TIME µs/div Test Circuit : A V = Test Circuit : A V = 5mV/div 5mV/div A V = V- = -.5V C L = 5pF 5mV/div 5mV/div A V = C L = 5pF TIME µs/div TIME 25ms/div 5mV/div A V = - V- = -.5V R L = 5kΩ R F = 2kΩ TIME µs/div TIME µs/div M9999-2276 8 February 26
Test Circuit 4: A V = - Test Circuit 4: A V = - 5mV/div A V = - V- = -.5V R F = 2kΩ 5mV/div A V = - R F = 2kΩ 5mV/div TIME µs/div Rail to Rail Output Operation Rail to Rail Output Operation 2V/div 2V/div 2V/div A V = 2 R F = 2kΩ V PP = 5V TIME 25µs/div Rail to Rail Output Operation 2V/div 2V/div A V = 2 V- = -.5V R F = 2kΩ V PP = 2.7V TIME 25µs/div Rail to Rail Output Operation V/div V/div 5mV/div TIME ms/div A V = 2 V- = -.5V R L = 5kΩ R F = 2kΩ V PP = 2.7V 2V/div A V = 2 R L = 5kΩ RF = 2kΩ V PP = 5V TIME 25µs/div TIME 25µs/div February 26 9 M9999-2276
Large Signal Pulse Response Test Circuit : A V = Large Signal Pulse Response Test Circuit : A V = A V = V- = -.5V C L = pf R L = 5kΩ A V = C L = pf R L = 5kΩ 5mV/div Positive Slew Rate =.4V/µs Negative Slew Rate =.22V/µs 5mV/div Positive Slew Rate =.V/µs Negative Slew Rate =.8V/µs TIME µs/div TIME µs/div M9999-2276 February 26
Applications Information Power Supply Bypassing Regular supply bypassing techniques are recommended. A µf capacitor in parallel with a.µf capacitor on both the positive and negative supplies are ideal. For best performance all bypassing capacitors should be located as close to the op amp as possible and all capacitors should be low ESL (equivalent series inductance), ESR (equivalent series resistance). Surface-mount ceramic capacitors are ideal. February 26 M9999-2276
Package Information SC7-5 MICREL INC. 28 FORTUNE DRIVE SAN JOSE, CA 95 USA TEL + (48) 944-8 FAX + (48) 474- WEB http://www.micrel.com This information furnished by Micrel in this data sheet is believed to be accurate and reliable. However no responsibility is assumed by Micrel for its use. Micrel reserves the right to change circuitry and specifications at any time without notification to the customer. Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser's use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser's own risk and Purchaser agrees to fully indemnify Micrel for any damages resulting from such use or sale. 22 M9999-2276 2 February 26