MIC62 MIC62 IttyBitty Operational Amplifier General Description The MIC62 IttyBitty op amp is a general-purpose, highperformance, single- or split-supply, operational amplifier in a space-saving, surface-mount package. The MIC62 operates from V to 2V, single or differential (split) supply. The input common-mode range includes ground. The device features a 2.5MHz unity gain bandwidth, 6V/µs slew rate, and is internally unity-gain compensated. Inputs are protected against reverse polarity (input voltage less than V ) and ESD (electrostatic discharge). Output is current limited for both sourcing and sinking. Output short circuits of unlimited duration are allowed, provided the power dissipation specification is not exceeded. The MIC62 is available in the tiny, 5-lead SOT-2-5 surface-mount package. Features V to 2V operation Small footprint package Unity gain stable 2.5 MHz unity gain bandwidth 6V/µs typical slew rate Short circuit protected Applications Analog blocks Active filtering Ordering Information Part Number Marking Temp. ange Package Standard Pb-Free Standard Pb-Free MIC62-BM5 MIC62-YM5 A A ºC to +85ºC SOT-2-5 Pin Configuration IN+ V OUT 2 A 5 IN V+ Part Identification Functional Configuration IN+ V OUT 2 5 IN V+ SOT-2-5 (M5) Pin Description Pin Number Pin Name Pin Function OUT Amplifier Output 2 V Negative Supply: Negative supply for split supply application or ground for single supply application. IN+ Noninverting Input IN Inverting Input 5 V+ Positive Supply IttyBitty is a trademark of 28 Fortune Drive San Jose, CA 95 USA tel + (8) 9-8 fax + (8) 7- http://www.micrel.com April 26 MIC62
MIC62 Absolute Maximum atings Supply Voltage (V V+ V V )... 6V or ±8V Differential Input Voltage (+ )... ±6V Input Voltage (+, )...(V V.V) to V V+ Output Short Circuit Current Duration... Operating atings Supply Voltage...V to 2V Ambient Temperature ange... C to +85 C SOT-2-5 Thermal esistance (θ JA )... 22 C/W (mounted to printed circuit board) Electrical Characteristics (Differential Supply) V+ = +5V, V = 5V, V CM = V; L = 2kΩ; T A = 25 C, bold values indicate C T A +85 C, T A = T J ; unless noted Symbol Parameter Condition Min Typ Max Units V OS Input Offset Voltage 2 7 mv TCV OS Average Input Offset Drift Note 7 µv/ C I B Input Bias Current 5 25 na I OS Input Offset Current 8 na V CM Input Voltage ange +.5 +.8 V 5. 5. V CM Common Mode ejection atio V CM = +.5V, 5.V 65 db PS Power Supply ejection atio = ±2.5V to ±5V 65 db A VOL Large Signal Voltage Gain V O = ±V 25 8 V/mV Maximum Output Voltage Swing ±2.5 ± V B W Bandwidth 2.5 MHz S Slew ate 6 V/µs I SC Output Short Circuit Current Sourcing or sinking 5 ma I S Supply Current. 2. ma Electrical Characteristics (Single Supply) V+ = +5V, V = V, V CM =.V; T A = 25 C, bold values indicate C T A +85 C, T A = T J ; unless noted Symbol Parameter Condition Min Typ Max Units V OS Input Offset Voltage 2 7 mv TCV OS Average Input Offset Drift Note 7 µv/ C I B Input Bias Current 65 25 na I OS Input Offset Current 8 na V CM Input Voltage ange +.5 +.7 V. V CM Common Mode ejection atio V CM = V to.5v 5 7 db PS Power Supply ejection atio = ±2.5V to ±5V 65 5 db A VOL Large Signal Voltage Gain V O =.5V to.5v, L = 2k 5 7 V/mV Maximum Output Voltage Swing L = k to +.8 +. V L = k to +5V +. +.2 V I SC Output Short Circuit Current Sourcing or sinking 2 ma I S Supply Current.2.8 ma General Note: Devices are ESD protected; however, handling precautions are recommended. Note : Not production tested. MIC62 2 April 26
MIC62 Typical Characteristics.. Supply Current 9 8 7 Input Bias Current = 5V 2 5 Input Offset Current.2. = 5V 6 5 5 = 5V. - -2 2 6 8 TEMPEATUE ( C) - -2 2 6 8 TEMPEATUE ( C) - -2 2 6 8 TEMPEATUE ( C).5..5 Supply Current vs. Supply Voltage 5 5 2 25 SUPPLY VOLTAGE (V) 2 8 6 2-2.. Voltage Gain vs. Frequency, FEQUENCY (khz), 2 - Gain and Phase vs. Frequency GAIN PHASE 72 5 9 5 8 225-2.. 27 FEQUENCY (MHz) P HASE ( ) Large-Signal Transient esponse Small-Signal Transient esponse INPUT VOLTAGE OUTPUT VOLTAGE +V V +V V A V = + L = 2k C L = pf = 5V 2µs/DIV INPUT VOLTAGE OUTPUT VOLTAGE +5mV 5mV +5mV 5mV A V = + L = 2k C L = pf = 5V 5ns/DIV April 26 MIC62
MIC62 25 2 5 5 Large-Signal Frequency esponse L = 2k T A = 25 C FEQUENCY (khz) Common Mode ejection atio vs. Frequency 9 8 7 6 5.. FEQUENCY (khz) 2 9 8 7 6 Power Supply ejection atio vs. Frequency -PS +PS 5... FEQUENCY (khz) 65 6 Short Circuit Current 55 5 5 - -2 2 6 8 TEMPEATUE ( C).Hz to Hz Noise Wideband Noise = 5V = 5V NOISE VOLTAGE (µv/div) NOISE VOLTAGE (5µV/DIV) s/div 5ms/DIV MIC62 April 26
MIC62 Functional Diagram 5 V+ 2Ω IN 2Ω +IN C C MIC62 2 V () April 26 5 MIC62
MIC62 Applications Information Common-Mode ange and Output Voltage The input common-mode range of the MIC62 is from the negative supply voltage to.2v below the positive supply voltage. The output voltage swings within V of the positive and negative supply voltage. Voltage Buffer Figure shows a standard voltage follower/buffer. The output voltage equals the input voltage. This circuit is used to buffer a high impedance signal source. This circuit works equally well with single or split supplies. = Figure. Voltage Buffer Inverting Amplifier Figure 2 shows an inverting amplifier with its gain set by the ratio of two resistors. This circuit works best with split supplies, but will perform with single supply systems if the non-inverting input (+ input) is biased up above ground. 2 = 2 Figure 2. Inverting Amplifer Voltage Controlled Current Sink Figure is a voltage controlled current sink. A buffer transistor forces current through a programming resistor until the feedback loop is satisfied. Current flow is /. This circuit works with single or split supplies. High-Pass Filter Figure is an active filter with 2dB ( ) gain and a lowfrequency cutoff of Hz. The high gain-bandwidth of the MIC62 allows operation beyond khz. This filter configuration is designed for split supplies. µf µf 7.5k.µF 2k Figure a. High-Pass Filter (db) 2 - -2 k k FEQUENCY (Hz) Figure b. High-Pass Filter esponse Summing Amplifier Figure 5 is a single supply summing amplifier. In this configuration, the output voltage is the sum of V and V2, minus the sum of V and V. By adding more resistors to either the inverting or non-inverting input, more voltages may be summed. This single supply version has one important restriction: the sum of V and V2 must exceed the sum of V and V, since the output voltage cannot pull below zero with only a single supply. V V2 V V All resistors are equal. = V + V2 V V V + V2 > V + V for single supply operation,,, Figure 5. Summing Amplifier I Figure. Voltage Controlled Current Sink MIC62 6 April 26
MIC62 Package Information SOT-2-5 (M5) MICEL, INC. 28 FOTUNE DIVE SAN JOSE, CA 95 USA TEL + (8) 9-8 FAX + (8) 7- WEB http://www.micrel.com The 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 at Purchaser s own risk and Purchaser agrees to fully indemnify Micrel for any damages resulting from such use or sale. 999 Micrel, Incorporated. April 26 7 MIC62