| DG508 (pdf) |
Three ICs Produce Pure Sine Waves |
| DS0621-SDK |
App Note 114: TMEX Extended File Structure Revision 3.10 |
| DS1013 (pdf) |
App Note 14: Design Considerations for All-Silicon Delay Lines |
| DS1020 (pdf) |
App Note 107: DS1020/DS1021 8-Bit Programmable Delay Lines |
| DS1045 (pdf) |
Device Characteristics of the DS1045 Dual 4-Bit Programmable Delay Line |
| DS1075 |
Tech Brief 12: The Effects of High-Speed Design Techniques and Test Equipment Measurement |
| DS1075 |
Tech Brief 15: DS1075 EconOscillator: Power Dissipation Models |
| DS1075 |
Tech Brief 16: Accuracy: What do you really need? |
| DS1075 |
App Note 137: Using a DS1075 EconOscillator to Clock an 8051 Microprocessor |
| DS1075 |
Tech Brief 9: In-Circuit Reprogramming of the DS1075 EconOscillator |
| DS1075K |
Tech Brief 11: Using the DS1075K Development Kit to Program SOIC and TO-92 Packages |
| DS1075K |
Tech Brief 13: Modifying the DS1075K Board to Work With the DS1073 3.6 V EconOscillator |
| DS1202 |
App Note 118: Replacing the DS1202 with the DS1302 |
| DS1213 |
App Note 004: DS1213, DS1216, DS1613 Smart Socket/Smart Watch Options |
| DS1216 (pdf) |
DS1213, DS1216, DS1613 Smart Socket/Smart Watch Options |
| DS1216 (pdf) |
Using the Dallas Phantom Real-Time Clocks |
| DS1220 (pdf) |
Using Nonvolatile Static RAMs |
| DS1232 (pdf) |
Advantages of Using a MicroMonitor and a Simple Application Demonstrating the Use of a DS1232 |
| DS1233 |
App Note 051: How to Save Data During a Power Fail without Corrupting It |
| DS1236 (pdf) |
Designing a Nonvolatile 2M x 16 Memory Subsystem |
| DS1243 (pdf) |
Using the Dallas Phantom Real-Time Clocks |
| DS1267 |
Tech Brief 2: Dual-Polarity Amplifier is Controlled Digitally |
| DS1267 (pdf) |
Using Multiple DS1267 Digital Potentiometers With an 8051 Microprocessor Generating 3-Wire Signals |
| DS1283 (pdf) |
Watchdog Timekeeper |
| DS1287 |
Tech Brief 8: Problems and Solutions for the Year 2000 |
| DS12885 (pdf) |
Replacement for the MC146818A |
| DS12885 (pdf) |
Replacement for the MC146818 |
| DS12C887A (pdf) |
Crystal Considerations with Dallas Real-Time Clocks |
| DS1302 |
App Note 501: Interfacing 3-Wire Real-Time Clocks With A Microcontroller |
| DS1302 (pdf) |
Using the Dallas Tricklecharge Timekeeper |
| DS1306 |
App Note 502: Interfacing SPI Real Time Clocks With A Microcontroller |
| DS1307 (pdf) |
Interfacing the DS1307 with an 8051-Compatible Microcontroller |
| DS1315 (pdf) |
Using the Dallas Phantom Real-Time Clocks |
| DS1336 (pdf) |
Designing a Nonvolatile 2M x 16 Memory Subsystem |
| DS1380 (pdf) |
RAMport |
| DS1384 |
App Note 101: Using the Secure Microcontroller Watchdog Timer |
| DS1425 |
App Note 096: Dallas Buttons Ease Software Distribution Management |
| DS1425 |
App Note 097: Features, Advantages, and Benefits of Button-Based Security |
| DS1427 |
App Note 098:A New Architecture for Distributed Security |
| DS1602 |
App Note 030: Recording Power Cycling Information Using the DS1602/DS1603 |
| DS1602 (pdf) |
Algorithm for Converting Binary Seconds into Date/Time |
| DS1609 (pdf) |
Dual Port RAM |
| DS1615 (pdf) |
Using the DS1615 and DS1616 Temperature and Data Recorder |
| DS1620 |
App Note 067: Applying and Using the DS1620 in Temperature Control Applications |
| DS1620 |
App Note 068: Increasing Temperature Resolution on the DS1620 |
| DS1620 (pdf) |
High Resolution Temperature Measurement with Dallas Direct-to-Digital Temperature Sensors |
| DS1620 (pdf) |
Interfacing the DS1620 with a DS5000/8051 Microcontroller |
| DS1620 |
App Note 085: Interfacing the DS1620 to the Motorola SPI Bus |
| DS1632 (pdf) |
PC Chipset Power Fail and Reset Controller |
| DS1669 (pdf) |
LCD Contrast Control Using Dallas Semiconductor Digital Potentiometers |
| DS1669 |
Tech Brief 3: Digitally Control Phase Shift |
| DS1670 |
App Note 100: DS1670 Portable System Controller |
| DS1685 (pdf) |
Using the Multiplex Bus RTC Extended Features |
| DS1685 |
App Note 077: DS1685/87 AND DS17X85/87 Accessing Extended User RAM |
| DS1721 |
App Note 127: DS1721/DS1621 Compatibility |
| DS1802 (pdf) |
Audio Characterization Report for the DS1802 Dual Digital Audio Potentiometer |
| DS1803 (pdf) |
Controlling a DS1803 Digital Potentiometer Using an 8051 Microprocessor to Generate 2-Wire Signals |
| DS1804 (pdf) |
Controlling a DS1804 Using an 8051-Compatible Microcontroller |
| DS1820 |
App Note 122: Using Dallas' 1-Wire Chips in 1-Cell Li+ Battery Packs With Low-Side n-Channel Safety FETs Master |
| DS1820 |
App Note 104: Minimalist Temperature Control Demo |
| DS1867 |
App Note 087: DS1867 Power Supply Conditioning for EEPROM Wiper Storage |
| DS1982 |
App Note 084: Add-Only Memory for Secure Storage of Monetary Equivalent Data |
| DS1990A (pdf) |
Reading and Writing iButtons via Serial Interfaces |
| DS1991 (pdf) |
Reading and Writing iButtons via Serial Interfaces |
| DS1991 (pdf) |
Understanding and Using Cyclic Redundancy Checks with Dallas Semiconductor iButton® Products |
| DS1992 (pdf) |
Reading and Writing iButtons via Serial Interfaces |
| DS1994 |
App Note 060: DS1994 Memory/Time iButton |
| DS1WM |
Tech Brief 1: 1-Wire Net Design Guide |
| DS1WM |
App Note 119: Embedding the 1-Wire Master |
| DS1WM |
App Note 120: Communicating through the 1-Wire Master |
| DS1WM |
App Note 126: 1-Wire Communication Through Software |
| DS2107A |
App Note 072: DS2107A Power Down Capacitance |
| DS2107A |
App Note 070: DS2107A SCSI Bus Waveforms |
| DS2107A |
App Note 071: DS2107A Thermal Considerations |
| DS2107A |
App Note 073: DS2107A Active Negation |
| DS21352 |
App Note 360: DS21352/DS21552 vs. DS2152 |
| DS21352 |
App Note 370: Using RCLK in a BITS Application |
| DS21354 |
App Note 361: DS21354/DS21554 vs. DS2154 |
| DS2141 |
App Note 309: Interfacing to the Fractional T1 and E1 |
| DS2141 |
App Note 302: DS2141, DS21Q41, DS21Q43 8-MHz System Clock Operation |
| DS2141A |
App Note 326: DS2141A, DS2143, DS2151, DS2153 Interfacing to a Nonmultiplexed Bus |
| DS2141A |
App Note 335: DS2141A, DS2151 Controlling the FDL |
| DS2141A |
App Note 306: DS2141A, DS2143 Three Channel Drop and Insert |
| DS2141A |
App Note 308: DS2141A, DS2143, DS2151 and DS2153 Interfacing to the SGS-Thomson M3488 |
| DS2141A |
App Note 313: DS2141A, DS2143, DS2151, DS2153 Interfacing to the Mitel MT8980D |
| DS2141A |
App Note 345: DS2141A, DS2151, DS2152 SLC-96 |
| DS2141A |
App Note 338: DS2141A, DS2151 Alarm Set and Clear Criteria |
| DS2141A |
App Note 315: DS2141A, DS2143, DS2151, DS2153 Interfacing to the Siemens PEB2045 |
| DS2141A |
App Note 339: DS2141A, DS2151 D4 Framing Applications |
| DS2141A |
App Note 314: DS2141A, DS2142, DS2151, DS2153 Per-Channel Loopback |
| DS2141A |
App Note 328: DS2141A Creating a DS/ESF Channel Service Unit |
| DS2151 |
App Note 341: DS2151, DS2153 Device Identification |
| DS2151 |
App Note 311: DS2151, DS2153 Interfacing to the Hitachi HD64570 |
| DS2151 |
App Note 353: General Network Interface Design Criteria for the DS2151 and DS2152 |
| DS2151 |
App Note 329: DS2151 Special Modes |
| DS2151 |
App Note 316: DS2151, DS2153 Interfacing to the PMC-Sierra PM7345 |
| DS2151 |
App Note 342: Initialization and Programming |
| DS2151 |
App Note 351: Transformer Selection Guide |
| DS2151 |
App Note 323: DS2151, DS2152, DS2153, DS2154 T1/E1 Line Monitor |
| DS2151 |
App Note 312: DS2151, DS2153 Interfacing to the PEB20320 |
| DS2151 |
App Note 305: DS2151, DS2153 Interfacing to the Brooktree Bt8221 and Bt8222 |
| DS2151 |
App Note 327: DS2151, DS2153 Creating a T1/E1 Channel Service Unit |
| DS2151 |
App Note 347: Converting the DS2151/DS2153 Demo Kits |
| DS2151 |
App Note 318: DS2151, DS2153 Interfacing to the MC68MH360 QUICC32 |
| DS2151 |
App Note 325: DS2151, DS2152, DS2153, DS2154 Crystal Selection Guide |
| DS2151 |
App Note 304: DS2151, DS2153 Interfacing to the AT&T T7270 |
| DS2151 |
App Note 324: DS2151, DS2152, DS2153, DS2154 Secondary Over-Voltage Protection |
| DS2151 |
App Note 337: DS2151 Implementation of ANSI T1.231-1993 |
| DS2151 |
App Note 303: DS2151, DS2153 Interfacing to the ADSP-2181 |
| DS2151Q (pdf) |
App Note 351: Transformer Selection Guide |
| DS2152 |
App Note 354: DS2152, DS2154 Clock Map |
| DS2152 |
App Note 317: DS2152, DS2154 Interfacing to the Siemens PXB4220 |
| DS2152 (pdf) |
App Note 350: Provision Your DS2152 or DS2154 Hardware Design for the Next Generation Devices |
| DS2152 |
App Note 321: DS2152, DS2154 Interfacing to the IGT ALL1 SAR (WAC-021-C) |
| DS2152 |
Tech Brief 6: Multi-Channel T1/E1 Solutions |
| DS2152 |
Tech Brief 7: DS2152 and DS2154 8 MHz System Clock Operation |
| DS2152 |
App Note 346: Converting the DS2152/DS2154 Demo Kits |
| DS2152 |
App Note 307: DS2152, DS2154, DS2151 and DS2153 Three Channel Drop and Insert |
| DS2152 |
App Note 301: DS2152, DS2154 8-MHz System Clock Operation |
| DS2152 |
App Note 319: DS2152, DS2154 Interfacing to the MC68MH360 QUICC32 |
| DS2152L (pdf) |
App Note 349: DS2152L vs. DS2151Q |
| DS2153 |
App Note 352: General Network Interface Design Criteria for the DS2153 and DS2154 |
| DS2153 |
App Note 330: DS2153 Special Modes |
| DS2153 |
App Note 340: DS2153 ETS-300-011 Remote Alarm Generation |
| DS2153 |
App Note 322: DS2153, DS2154 Selectable 120 and 75-OHM E1 Interface |
| DS2154L (pdf) |
App Note 348: DS2154L vs. DS2153Q |
| DS2172 |
App Note 332: DS2172 Simplified Receiver Operation |
| DS2172 |
App Note 334: DS2172, Interfacing to the DS2141, DS2143, DS21Q41, DS21Q43, DS2151, DS2152, DS2153, DS2154 |
| DS2172 |
App Note 333: DS2172 Pattern Synchronization |
| DS2172 |
App Note 331: DS2172 V.54 Modem Test Patterns |
| DS21Q41 |
App Note 310: D4 Framing and Signaling |
| DS21Q41 |
App Note 336: Transparent Operation |
| DS21Q41 |
App Note 320: DS21Q41, DS21Q43 Interfacing to the MC68MH360 QUICC32 |
| DS21Q42 (pdf) |
App Note 357: DS21Q42 vs. DS21Q41B |
| DS21Q42 (pdf) |
App Note 355: Test Registers |
| DS21Q44 (pdf) |
App Note 356: DS21Q44 vs. DS21Q43A |
| DS21X5Y (pdf) |
App Note 359: Interfacing to the TMS320C54x to the DS21X5Y |
| DS2229 (pdf) |
Designing a Nonvolatile 2M x 16 Memory Subsystem |
| DS232A (pdf) |
App Note 083: Fundamentals of RS-232 Serial Communications |
| DS232A |
Tech Brief 10: ESD Considerations for RS-232 Drivers |
| DS2407 (pdf) |
Minimalist Temperature Control Demo |
| DS2409 (pdf) |
Quick Guide to 1-Wire net Using PCs and Microcontrollers |
| DS2409 |
App Note 108: MicroLAN—In The Long Run |
| DS2434 |
App Note 124: Battery Considerations For Today's Low-Power, Long-Life Solid State Devices |
| DS2437 (pdf) |
NiCD/NiMH Intelligent Battery System Reference Design Using the DS2437 |
| DS2437 |
App Note 126: 1-Wire Communication Through Software |
| DS2438 |
App Note 125: Using Dallas Battery Management ICs with High Voltage Cell Packs |
| DS2438 (pdf) |
Lithium-Ion Cell Fuel Gauging with Dallas Semiconductor Devices |
| DS2438 |
App Note 123: Recommended ESD Protection and Circuit Placement for the DS2438 in Li+ Cell Pack Master |
| DS2490 (pdf) |
DS2490 Universal Serial Bus Descriptors |
| DS2502 (pdf) |
UniqueWare Project Setup Manual Revision 2.00B |
| DS2760 |
App Note 138: Using the DS2760 in Multiple-Cell Applications |
| DS2760 |
App Note 121: Inaccuracies of Estimating Remaining Cell Capacity with Voltage Measurements Alone |
| DS2760 |
App Note 128: Testing and Calibrating a DS2760 Based Circuit |
| DS3134 (pdf) |
App Note 368: Examples of DS3134 CHATEAU Applications |
| DS3134 |
App Note 365: DS3134 CHATEAU Initialization Steps |
| DS3134 (pdf) |
App Note 364: DS3134 Step By Step Configuration—Bridge Mode |
| DS3134 (pdf) |
App Note 358: DS3134 Application Note: PCI Bus Utilization |
| DS3134 (pdf) |
App Note 363: DS3134 Step By Step Configuratuion—Configuration Mode |
| DS3134 |
App Note 366: DS3134 CHATEAU Test Registers |
| DS3134 (pdf) |
App Note 369: DS3134 Step By Step Configuration Unchannelized Port—Configuration Mode |
| DS3150 |
App Note 362: Replacing the TDK 78P7200/2241 with the DS3150 |
| DS32KHz |
App Note 701: Using the DS32KHz with Dallas RTCs |
| DS5000 (pdf) |
Interfacing the DS1620 with a DS5000/8051 Microcontroller |
| DS5000 |
App Note 093: Design Guidelines for Microcontrollers Incorporating NVRAM |
| DS5001FP |
App Note 094: Using the Secure Microcontroller with EPROM/ROMD |
| DS5002FP (pdf) |
DS5002FP Memory Expansion Techniques |
| DS80C310 |
App Note 091: Microcontroller Design Guidelines for Reducing ALE Signal Noise |
| DS80C320 (pdf) |
Using the High-Speed Micro's Serial Ports |
| DS80C320 (pdf) |
Using the High-Speed Micro's Watchdog Timer |
| DS80C320 (pdf) |
Memory Expansion with the High-Speed Microcontroller Family |
| DS80C320 (pdf) |
High-Speed Micro Memory Interface Timing |
| DS80C320 (pdf) |
DS80C320 Memory Interface Timing |
| DS80C320 |
App Note 056: The DS80C320 as a Drop-In Replacement for the 8032 |
| DS87C520 |
App Note 102: Using the High-Speed Microcontroller as a Bootstrap Loader |
| DS87C530 (pdf) |
Using the DS87C530 Real-Time Clock |
| DS87C550 |
App Note 002: The DS87C550 as an Upgrade for 8051 Derivatives |
| DS87C5x0 (pdf) |
Using Power Management with the DS87C5x0 |
| FAQs |
Communication Products: Frequently Asked Questions |
| FAQs |
Memory Products - Frequently Asked Questions |
| FAQs |
Silicon Timed Circuits: Frequently Asked Questions |
| FAQs |
Digital Potentiometers: Frequently Asked Questions |
| FAQs |
Nonvolatile Controllers: Frequently Asked Questions |
| FAQs |
Microcontrollers: Frequently Asked Questions |
| FAQs |
EconOscillators: Frequently Asked Questions |
| FAQs |
Data Loggers: Frequently Asked Questions |
| FAQs |
CPU Supervisors: Frequently Asked Questions |
| ICL7611 |
P-FET Linear Regulator Has Low Dropout Voltage |
| ICL7612 (pdf) |
Micropower Circuit Monitors Positive Supply Current |
| ICL7612A |
Step-Up/Step-Down Current Source Charges Batteries |
| ICL7621 |
Boost/Linear Regulator Derives 5V From Four Cells |
| ICL7631 (pdf) |
Buffering Scheme Drives Large LCDs |
| ICL7660 (pdf) |
Lower Operating Frequency Improves ICL7660 Voltage-Conversion Efficiency |
| ICL8069 (pdf) |
Dummy Load Maintains Constant Current |
| ICM7555 (pdf) |
Proximity Detector Features Ultrasonic Transducers |
| ICM7556 (pdf) |
One-Hour Battery Charger Has Switch-Mode PWM Control |
| MAX101A |
Novel Storage Idea Supports Ultra-Fast Data Acquisition |
| MAX1044 |
High-Frequency Switching IC Powers Portable Telephone |
| MAX1044 |
PC Printer Port Controls Data Logger |
| MAX108 |
INL/DNL Measurements for High-Speed ADCs |
| MAX1200 |
Understanding Pipelined ADCs |
| MAX125 |
ADCs for Simultaneous Sampling |
| MAX132 |
PC Printer Port Controls Data Logger |
| MAX1444 |
Multiply Your Sampling Rate with Time-Interleaved Data Converters |
| MAX147 |
Adjustment-Free Inclinometer Operates On +2.7V |
| MAX1480B |
RS-485 Data Interface Gives Isolated, Full-Duplex Operation |
| MAX1614 |
High-Voltage Circuit Breaker Protects To 26V |
| MAX1616 |
Emitter-Follower Boosts Linear Regulator's Output Current |
| MAX1626 |
Miniature Temperature Monitors Drive 3-Speed Fan Controller |
| MAX1627 |
Two AA Cells Power Step-Down Regulator |
| MAX163 (pdf) |
Sample/Hold Has Zero Droop and Infinite Hold |
| MAX1637 |
The 3.3V Input Step-Down Converter |
| MAX1638 |
Power Supplies for Telecom Systems |
| MAX1660 |
Evaluating Accuracy of Coulomb-Counting Fuel-Gauging Systems |
| MAX1683 |
Tripler Converts 5V to 15V |
| MAX1692 |
Current-Limit Circuit for the Buck Regulator |
| MAX1692 |
All-Ceramic 320mA Step-Down Converter for USB |
| MAX1692 |
Maxim's Integrated Power Supplies Provides a Highly Reliable and Space-Saving Approach to Post-Regulators |
| MAX170 (pdf) |
DAC/ADC Combination Finds Square Roots |
| MAX1701 |
3.3V Lithium-Ion-Cell Supply Requires One Inductor |
| MAX1705 |
Trading Performance for Cost in Portable Power Supplies |
| MAX1705 |
Wireless-Modem Power for Hand-Held Devices |
| MAX1706 |
Two AA Cells Power Step-Down Regulator |
| MAX1771 |
Negative Buck Regulator Employs Step-Up Controller |
| MAX1771 |
Step-Up Supply Charges Battery While Serving Load |
| MAX1771 |
HFDN-08.0: APD Bias Circuit Has Adjustable Output |
| MAX1771 |
Supply Generates 5V From Solar-Cell Power |
| MAX1771 |
APD Bias Circuit Has Adjustable Output |
| MAX1771 |
Circuit Connection Adds Current-Mode Operation To PFM Boost Converters |
| MAX1771 |
Off-The-Shelf Transformer Limits Capacitor Inrush Current |
| MAX1771 |
Adjustable LNB Power Pupply Is DiSEqC Compatible |
| MAX1772 |
Choices for Battery-Charging System Architecture |
| MAX1772 |
Input Current Limiting in Battery Chargers for Mobile Computing Applications |
| MAX1790 |
All-Ceramic 200mA Step-Up Converter for USB |
| MAX1820 |
W-CDMA Power Supply Dramatically Improves Transmit Efficiency |
| MAX186 |
12-Bit ADC Upgrades µC s Internal 8-Bit ADC |
| MAX187 |
PC Serial Port Drives 12-Bit A/D Converter |
| MAX187 |
Interfacing the MAX187 to the TMS320C3X Evaluation Module |
| MAX189 |
PC Printer Port Controls I-V Curve Tracer |
| MAX190 (pdf) |
12-Bit Sampling A/D Converter Conserves Power |
| MAX195 |
Interfacing the MAX195 to the TMS320C3X Evaluation Module |
| MAX195 |
Understanding SAR ADCs |
| MAX197 |
Analog-Signal Data Acquisition in Industrial Automation Systems |
| MAX2108 |
REP026: Direct-Conversion Tuner Optimized for Operation from 950MHz to 1750MHz |
| MAX211 |
Redundant-Transceiver RS-232 Link Has ±40V Overvoltage Protection |
| MAX220 |
PC Serial Port Drives 12-Bit A/D Converter |
| MAX2240 |
MAX2240 PA in Bluetooth Communication System: Performance Review |
| MAX2242 |
The MAX2242 Power Amplifier: Crucial Application Issues |
| MAX2242 |
A 22.5dBm 2.4GHz Linear Power Amplifier for 802.11b WLAN Applications |
| MAX2242 |
+23dBm PA and PA Predriver with 37% Efficiency for 2.4GHz FHSS WLAN Applications |
| MAX2242 |
Block Diagram for 2.4GHz IEEE802.11b DSSS WLAN Transceiver Application |
| MAX2264 |
REP014: PA Provides -4dB ACPR at 28.5dBm Output |
| MAX2264 |
REP015: Dual-Path CDMA PA Tuned for High Linearity |
| MAX2265 |
REP009: Cellular PA Has Good TDMA Results in Small PCB Layout Area |
| MAX2265 |
REP013: Low-Cost CDMA RF PA Tuned to Meet IS-95 Cellular-Band Specs |
| MAX2266 |
The MAX2266 Power Amplifier for the CDMA Cellular Band with the PIN Diode Switch |
| MAX2269 |
The MAX2269 Power Amplifier for the Japanese CDMA Cellular Band with the PIN Diode Switch |
| MAX2269 |
REP006: Linear RF Power Amplifier Matched for High Efficiency at Low Power |
| MAX2291 |
MAX2291 for W-CDMA Application |
| MAX2309 |
Block Diagram for Radio Chipset for TD-SCDMA Handset Design Application |
| MAX2309 |
MAX2309/MAX2312 at 190MHz IF for W-CDMA |
| MAX2310 |
IF Tank Design for the MAX2310 |
| MAX2320 |
REP005: Tuned Front End for Dual-Band CDMA for Use with Low-Cost 85MHz IF SAWs |
| MAX2321 |
REP002: Dual-Band IS136 TDMA RF Front-End Application |
| MAX2322 |
The MAX2322 Used in W-CDMA Applications |
| MAX2322 |
Maxim Wireless/RF Power Amplifier Selector Guide |
| MAX2323 |
REP003: Cellular Front-End IC in Automobile Application |
| MAX2323 |
REP018: Dual-Band Dual-Mode FE IC with Common 183.6MHz IF |
| MAX2323 |
REP021: Front End for 2.5GHz GlobalStar +IS-95 |
| MAX2323 |
REP020: Dual-Band Dual-Mode FE IC with Common 210MHz IF |
| MAX2323 |
REP019: Tuned Dual-Band Front-End CDMA IC with Single 110MHz IF |
| MAX2323 |
REP012: Cellular LNA Achieves +20dBm IIP3 in Low-Gain High-Linearity Mode |
| MAX2323 |
Triple/Dual/Single Mode CDMA LNA/Mixers |
| MAX2323 |
REP008: Dual-Band Front-End IC Tuned for CDMA, PCS, and AMPS at a Common 85MHz Low IF |
| MAX2323 |
REP007: Cellular Front-End IC Drives IFR3100 IF Demodulator |
| MAX2324 |
REP011: Front-End Japanese CDMA IC Uses 110MHz IF |
| MAX2324 |
REP001: AMPS FM Mixer Trades Off IIP3 for Gain |
| MAX2325 |
REP016: Dual-Band Front End for Japanese Cellular CDMA at 110MHz IF |
| MAX2338 |
REP010: Dual-Band IS-136 FE IC at 183MHz IF |
| MAX2338 |
REP017: Dual-Band Triple-Mode IC Uses 183MHz for Both CDMA and AMPS IFs |
| MAX2360 |
IF Tank Design for the MAX2360 |
| MAX2383 |
REP023: 3.5GHz Upconverter from 350MHz Achieves 9dB Gain and 1.3dBm IIP3 |
| MAX2387 |
MAX2388 at 190 MHz IF for W-CDMA |
| MAX2388 |
W-CDMA Superheterodyne Reference Design: V1.0 RF Transceiver Description |
| MAX2452 |
SSB Modulator Draws Only 5mA At 2.7V |
| MAX253 |
Draw 150mW Of Isolated Power From Off-Hook Phone Line |
| MAX253 |
RS-485 Data Interface Gives Isolated, Full-Duplex Operation |
| MAX262 (pdf) |
Programmable Universal Filter Implements C-Message Weighting Function |
| MAX2620 |
High-Frequency Clock Signal for Ultra-High-Speed ADC |
| MAX2620 |
Crystal Oscillator Has Dual or Differential Outputs |
| MAX2640 |
REP025: Custom-Tuned LNA at 345MHz for Wireless Security System |
| MAX2641 |
REP024: LNA Optimized for GPS |
| MAX2644 |
Block Diagram for 2.4GHz ISM-Band FHSS Solutions: Bluetooth, HomeRF, DECT Application |
| MAX2644 |
REP004: Custom-Tuned 2.35GHz LNA for a Mobile Data Receiver |
| MAX265 (pdf) |
Filter Network Combines Antialiasing And Sinc Compensation |
| MAX2683 |
The MAX2683 Low-Cost High-Performance 3.5GHz Upconverter |
| MAX2684 |
REP022: 3.5GHz RF Upconverter from 900MHz Achieves 5dB Gain and 5dBm IIP3 |
| MAX270 (pdf) |
Three ICs Produce Pure Sine Waves |
| MAX270 (pdf) |
µP-Supervisor Chip Controls Programmable Filter |
| MAX2721 |
Block Diagram for a Radio Design Solution for a Satellite ISP Application |
| MAX2721 |
MAX2721 Direct-Frequency Upconverter Minimizes Chip Count and Is Ideal for Wideband Application |
| MAX274 (pdf) |
Remove DC Offset From Lowpass Filters |
| MAX2740 |
Block Diagram for Maxim Solutions for GPS Applications |
| MAX275 (pdf) |
Add Digital Adjustment To Continuous-Time Filters |
| MAX292 |
Sine Wave Generator Is Crystal Accurate |
| MAX293 |
Telephone Tone Generator Requires No Trimming |
| MAX3080 |
Trim the Fat Off RS-485 Designs |
| MAX3097 |
New RS-485 IC Increases System Reliability and Fault Detection in Motor-Control Circuits |
| MAX3185 |
Selecting and Using RS-232 Interface Parts for Your Power Supply Voltages |
| MAX319 |
Analog Switches Operate With 3V Or 5V Supplies |
| MAX3212 |
Serial-Data Interface Chip Supplies Bipolar Voltages |
| MAX3221 |
Multiplexer Enables Pseudomultidrop RS-232 Transmission |
| MAX3238E |
RS-232 Features Explained |
| MAX325 |
Tiny Analog Switch Alleviates I2C Address Conflicts |
| MAX3265 (pdf) |
HFDN-11.0: Using MAX3265 LOS in GBICs |
| MAX3265 (pdf) |
HFDN-03.0: Interfacing the MAX3265 to the MAX3875 |
| MAX3266 (pdf) |
HFAN-03.0.0: Accurately Estimating Optical Receiver Sensitivity |
| MAX329 (pdf) |
D/A Converter Generates Multiple Precision Outputs |
| MAX333 (pdf) |
Low-Cost Sample/Hold Includes Two ICs |
| MAX3485 |
Proper Wiring for RS-485 |
| MAX350 |
Serial-Control Multiplexer Expands SPI Chip Selects |
| MAX3510 |
Block Diagram for MAX3510 Upstream CATV Amplifier Application |
| MAX359 (pdf) |
Programmable Instrumentation Amplifier Provides Arbitrary Gain Values |
| MAX3667 |
HFDN-02.0: Driving A Laser Diode With the MAX3667 From A Single +3.3V Power Supply |
| MAX3670 (pdf) |
HFDN-13.0: Loop-Filter Configuration for the MAX3670 Low-Jitter PLL Reference Clock Generator |
| MAX3752 (pdf) |
HFAN-04.3.0: Jitter Specifications Made Easy: A Heuristic Discussion of Fibre Channel and Gigabit Ethernet Methods |
| MAX3752 (pdf) |
HFAN-04.5.2: Generating Jitter for Fibre Channel Compliance Testing |
| MAX3752 (pdf) |
HFDN-12.0: MAX3752 Impedance-Matching Experiments |
| MAX3800 (pdf) |
HFDN-10.0: Equalizing Gigabit Copper Cable Links with the MAX3800 |
| MAX3831 (pdf) |
HFDN-01.0: Disabling the Channel-Assignment Feature of the MAX3831 |
| MAX3866 (pdf) |
HFAN-03.0.1: Setting a LOP (Loss of Power) Threshold Level Equivalent to a BER Level of 10-3 |
| MAX3867 (pdf) |
HFDN-14.0: Modification of the MAX3867 for Burst-Mode Applications |
| MAX3867 (pdf) |
HFAN-02.0: Interfacing Maxim Laser Drivers With Laser Diodes |
| MAX3869 (pdf) |
HFAN-02.2.0: Extinction Ratio and Power Penalty |
| MAX3869 (pdf) |
HFAN-02.1.0: Laser Driver Parametric Calculator |
| MAX3875 (pdf) |
HFAN-01.1: Choosing AC-Coupling Capacitors |
| MAX3875 (pdf) |
HFAN-04.0.1: A Brief Introduction to Jitter in Optical Receivers |
| MAX3875 (pdf) |
HFAN-04.5.0: Measuring Deterministic Jitter with a K28.5 Pattern and an Oscilloscope |
| MAX3875 (pdf) |
HFAN-04.0.2: Converting between RMS and Peak-to-Peak Jitter at a Specified BER |
| MAX3875 (pdf) |
HFAN-01.0: Introduction to LVDS, PECL, and CML |
| MAX3881 (pdf) |
HFAN-01.0.1: Interfacing Single-Ended PECL to Differential PECL and Differential PECL to Single-Ended PECL |
| MAX3930 (pdf) |
HFDN-04.0: Simulating Direct Laser Modulation with the MAX3930 |
| MAX3950 (pdf) |
HFAN-05.1.0: Single-Ended and Differential S-Parameters |
| MAX3950 (pdf) |
HFDN-07.2: Circuit Card Layout Considerations for 10Gbps Current Mode Logic Inputs on the MAX3950 EVKIT |
| MAX399 |
PC Printer Port Controls Data Logger |
| MAX400 (pdf) |
Programmable Instrumentation Amplifier Provides Arbitrary Gain |
| MAX400 (pdf) |
D/A Converter Generates Multiple Precision Outputs |
| MAX400 (pdf) |
DAC/ADC Combination Finds Square Roots |
| MAX400 |
Simple Circuit, Measures Battery Impedance |
| MAX403 (pdf) |
Proximity Detector Features Ultrasonic Transducers |
| MAX406 (pdf) |
Low-Power Op-Amp Reduces Cable Costs for pH Probe |
| MAX406 (pdf) |
Op-Amp Inputs Provide Ultra Low-Leakage Clamps |
| MAX406 (pdf) |
Proximity Detector Features Ultrasonic Transducers |
| MAX406A (pdf) |
Single Coax Carries Power And Signal For Remote pH Measurement |
| MAX407 |
Dual Comparator Forms Temperature-Compensated Proximity Detector |
| MAX4124 |
Visible-Laser Driver Has Digitally Controlled Power Modulation |
| MAX4124 |
Small Photodiode Receiver Handles Fiber Optic Data Rates To 800kbps |
| MAX4130 |
Extending Soft-Start |
| MAX4130 |
15V Input Converter Generates -185V at 50mA |
| MAX4130 |
5V Input Converter Generates -30V at 80mA |
| MAX4130 |
+12V Input Converter Generates -165V at 100mA |
| MAX417 |
Load Switcher Draws Only 6µA |
| MAX4172 |
High-Voltage Circuit Breaker Protects To 26V |
| MAX4172 |
Circuit Breaker Handles Voltages to 32V |
| MAX4271 |
Flexible Current Limiter |
| MAX430 (pdf) |
Thermocouple Pre Amp |
| MAX436 (pdf) |
3rd-Order Highpass Filter Has Synthetic Inductor |
| MAX436 |
WTAs Provide Wideband, Bidirectional Drive For Coaxial Cable |
| MAX436 |
Third-Order Highpass Filter Has Synthetic Inductor |
| MAX436 |
Allpass Network Shifts 90° Over Wide Frequency Range |
| MAX436 |
LC Oscillator Has 1% THD |
| MAX436 |
Notch Filter Is DC-Accurate |
| MAX4372 |
High-Accuracy Current-Sense Amplifier Enables High Current Sensing and Current Sharing |
| MAX4501 |
Adjustable LNB Power Supply Is DiSEqC Compatible |
| MAX4539 |
Calibration-Multiplexers Ease System Calibration |
| MAX4544 |
Split IF Application for Dual-Band Single-Mixer ICs |
| MAX455 (pdf) |
Single Coax Carries Video, Power, And Channel-Select Signals |
| MAX457 (pdf) |
Build High-GBW Op-Amp From A Dual Video Amplifier |
| MAX457 (pdf) |
Single Coax Carries Video, Power, And Channel-Select Signals |
| MAX4636 |
Circuit Provides Reverse-Battery Protection |
| MAX471 |
Circuit Guards Battery Against Polarity Reversal And High Current |
| MAX471 |
Current-Sense IC Prevents Overcurrent Damage |
| MAX471 |
Simple Circuit, Measures Battery Impedance |
| MAX472 |
Programmable Current Source Delivers 0A To 5A |
| MAX472 |
Step-Up Supply Charges Battery While Serving Load |
| MAX472 |
Variable, Linear Current Source Operates On 5V |
| MAX473 |
Linear Regulator Converts 3.3V To 2.9V |
| MAX478 |
DAC/uP-Supervisor Combination Improves Analog I/O Reliability |
| MAX478 |
PC Printer Port Controls I-V Curve Tracer |
| MAX480 (pdf) |
Dummy Load Maintains Constant Current |
| MAX480 |
Battery-Powered Circuit Measures Milli Ohms and Micro Ohms |
| MAX480 (pdf) |
Voltage-Output D/A Converter Offers Low-Power Operation And Shutdown |
| MAX480 (pdf) |
Op-Amp Adds Short-Circuit Protection to High-Side Switch |
| MAX480 (pdf) |
Single Coax Carries Power And Signal For Remote pH Measurement |
| MAX481E |
Explanation of Maxim RS-485 Features |
| MAX483 |
RS-485 Data Interface Gives Isolated, Full-Duplex Operation |
| MAX492 |
PC Printer Port Controls I-V Curve Tracer |
| MAX492 |
SSB Modulator Draws Only 5mA at 2.7V |
| MAX494 |
SSB Modulator Draws Only 5mA at 2.7V |
| MAX495 |
Synchronous Buck-Regulator Output Terminates High-Speed Data |
| MAX495 |
Battery Charger Delivers 2.5A With >96% Efficiency |
| MAX495 |
Low-Power Circuit Reduces Vcc Audio Ripple By 40 dB |
| MAX5003 |
Isolated Power Supply Is Suitable For Telecom/Datacom Applications |
| MAX507 |
Programmable Current Source Delivers 0A To 5A |
| MAX5120 |
DAC/uP-Supervisor Combination Improves Analog I/O Reliability |
| MAX5160 |
Manually Operated Digital Pot Doesn't Need a Microprocessor |
| MAX5160 |
Current-Limit Switch is Digitally Programmable |
| MAX522 |
DAC-Powered Charge Pump Varies Negative Rail |
| MAX531 |
PC Printer Port Controls I-V Curve Tracer |
| MAX532 |
Programmable-Gain Amplifier, Using the MAX532 DAC |
| MAX5354 |
Visible-Laser Driver Has Digitally Controlled Power Modulation |
| MAX5360 |
Comparing the I2C Bus to the SMBus |
| MAX543 (pdf) |
DAC/ADC Combination Finds Square Roots |
| MAX552 |
DAC-Powered Charge Pump Varies Negative Rail |
| MAX5839 |
Deglitching Techniques for High-Voltage R-2R DACs |
| MAX6006 |
Creating Fast Line Transients |
| MAX603 |
Variable, Linear Current Source Operates On 5V |
| MAX608 |
Switch-Mode Converter Starts With Full Load Connected |
| MAX608 |
Step-Up/Step-Down Converter Generates 3.3V From Two Or Three Cells |
| MAX608 |
Circuit Connection Adds Current-Mode Operation To PFM Boost Converters |
| MAX6125 |
Visible-Laser Driver Has Digitally Controlled Power Modulation |
| MAX622 (pdf) |
High-Power Voltage Regulator Has Low Dropout Voltage |
| MAX623 (pdf) |
Op-Amp Adds Short-Circuit Protection to High-Side Switch |
| MAX627 |
Switch-Mode Supply Charges Battery While Serving Load |
| MAX627 (pdf) |
Inductorless Switching Regulator Boosts Input Voltage |
| MAX630 (pdf) |
Provide Battery Backup For Pseudo-Static RAMs |
| MAX630 (pdf) |
Uninterruptible 5V Supply Has Low Power Consumption |
| MAX6304 |
Pulsed Sensor Extends Battery Life |
| MAX6306 |
DAC/uP-Supervisor Combination Improves Analog I/O Reliability |
| MAX6311 |
Two AA Cells Power Step-Down Regulator |
| MAX634 |
Negative-Output Boost Regulator Has High Efficiency |
| MAX6346 |
Micropower Circuit Offers Automatic Shutdown and Low-Battery Lockout |
| MAX6373 |
Watchdog Timer Assumes Varied Roles |
| MAX638 |
48V-To-5V DC-DC Converter Borrows Power From Phone Lines |
| MAX638 (pdf) |
Bootstrapping Raises Efficiency Of DC-DC Converter |
| MAX639 (pdf) |
Battery Charger Regulates Input Voltage |
| MAX641 (pdf) |
Derive 12V From 8 V to 15V Input |
| MAX641 (pdf) |
Inductorless Switching Regulator Boosts Input Voltage |
| MAX641 (pdf) |
Regulated Charge Pump Delivers 50mA |
| MAX6513 |
Simple Circuit Activates Fan When Processor Heats Ups |
| MAX660 (pdf) |
Octal Trimpots Offer Rail-to-Rail Adjustments |
| MAX660 |
Comparator and Charge Pump Converts 3V to 5V |
| MAX660 |
Convert 3V To 5V Without Inductors |
| MAX660 |
Analog ICs for 3V Systems |
| MAX660 (pdf) |
Regulated Step-Up Converter Provides High Efficiency Without Inductors |
| MAX6605 |
Temperature-to-Digital Transfer Functions for the MAX6605 Driving an Eight-Bit ADC |
| MAX6605 |
Using Analog Temperature Sensors with ADCs |
| MAX663 |
PC Printer Port Controls I-V Curve Tracer |
| MAX664 |
PC Printer Port Controls I-V Curve Tracer |
| MAX6652 |
Monitoring Power-Supply Voltages with the MAX6652 |
| MAX666 |
PC Serial Port Drives 12-Bit A/D Converter |
| MAX666 |
JFET Increases Voltage Rating for Linear Regulator |
| MAX666 (pdf) |
MOSFET Pass Element Yields 100mV-Dropout Regulator |
| MAX666 (pdf) |
Increase Regulator Input Voltage |
| MAX666 (pdf) |
Low-Power DC-DC Converter Derives 5V From 3V Battery |
| MAX666 (pdf) |
Uninterruptible 5V Supply Has Low Power Consumption |
| MAX667 (pdf) |
Flyback Winding Adds 12V Output To 5V Buck Regulator |
| MAX667 |
Draw 150mW Of Isolated Power From Off-Hook Phone Line |
| MAX667 |
Low Battery Monitor Delays System Shutdown |
| MAX667 |
LAN Power Supply Generates Isolated 9V |
| MAX667 (pdf) |
Regulated Step-Up Converter Provides High Efficiency Without Inductors |
| MAX668 |
3.3V Supply Taps Power from the -12V PCI Bus |
| MAX668 |
SLIC Power-Supply Design |
| MAX668 |
Step-up Converter with LDO Beats SEPIC Efficiency |
| MAX668 |
Dual-Output SLIC Supply Shares Feedback |
| MAX668 |
Extending Soft-Start |
| MAX668 |
5V Input Converter Generates -30V at 80mA |
| MAX668 |
15V Input Converter Generates -185V at 50mA |
| MAX668 |
+12V Input Converter Generates -165V at 100mA |
| MAX674 (pdf) |
Single Coax Carries Power And Signal For Remote pH Measurement |
| MAX680 (pdf) |
MOSFET Pass Element Yields 100mV-Dropout Regulator |
| MAX680 (pdf) |
Load-Disconnect Switch Consumes Only 8µA |
| MAX681 |
Analog Switches Operate With 3V Or 5V Supplies |
| MAX6816 |
Switch Bounce and Other Dirty Little Secrets |
| MAX690 (pdf) |
µP-Supervisor Chip Controls Programmable Filter |
| MAX690 (pdf) |
Large Capacitor Replaces Backup Battery |
| MAX6900 |
Real-Time-Clock Selection and Optimization |
| MAX6900 |
Considerations for Real-Time-Clock Crystal Selection |
| MAX6901 |
Using Maxim RTCs with 3-Wire Interface |
| MAX6901 |
Interpreting Real-Time-Clock Registers |
| MAX709 |
5V, Non-Interruptible Power Supply Delivers 1A |
| MAX709 |
Boost Converter Yields Orderly Shutdown |
| MAX712 (pdf) |
One-Hour Battery Charger Has Switch-Mode PWM Control |
| MAX713 (pdf) |
One-Hour Battery Charger Has Switch-Mode PWM Control |
| MAX713 |
Switch-Mode Battery Charger Delivers 5A |
| MAX713 |
Quick-Charge IC Routes Step-Up Switcher Output To Battery |
| MAX713 |
Battery Charger Indicates Trickle Or Fast Charge |
| MAX713 |
Add-On Circuit Preconditions Battery Before Charging |
| MAX714 (pdf) |
Temperature Compensation Stabilizes LCD Contrast |
| MAX718 |
Dual Boost Regulator Handles Heavy Surge Currents |
| MAX720 |
5V, Non-Interruptible Power Supply Delivers 1A |
| MAX721 (pdf) |
Low-Power IC Converts -48V to 5V Without Transformer |
| MAX7219 |
Data Multiplexer Adds Cursor To LED-Display Driver |
| MAX722 |
Switch-Mode Supply Charges Battery While Serving Load |
| MAX7231 (pdf) |
Buffering Scheme Drives Large LCDs |
| MAX738 (pdf) |
Flyback Winding Adds 12V Output To 5V Buck Regulator |
| MAX739 |
Derive 5V From Four AA Cells |
| MAX7410 |
Switched-Capacitor IC Forms Notch Filter |
| MAX749 |
DC-DC Controller Drives Regulated Charge Pump |
| MAX752 |
Negative Buck Regulator Produces Positive Output |
| MAX7534 (pdf) |
D/A Converter Generates Multiple Precision Outputs |
| MAX756 |
Supply Circuitry Selects Main/Backup Voltage And Disconnects |
| MAX757 |
Power-Boost Circuit Powers Cellular Handset |
| MAX761 |
±5V Regulator Accepts Inputs From -2V to -12V |
| MAX761 |
Three-Input Supply Powers 3.3 Portables |
| MAX761 |
PFM Control Improves Dual-Output Step-Up Converter |
| MAX761 |
Low-Cost Step-Up/Step-Down Converter Accepts 2V To 16V Inputs |
| MAX761CSA |
-12V to -5V/400mA Regulator Ensures Sequencing With 5V Rail |
| MAX764 |
Autotransformer Regulator Inverts 12V To -12V |
| MAX770 |
Boost/Linear Regulator Derives 5V From Four Cells |
| MAX770 |
Quick-Charge IC Routes Step-Up Switcher Output To Battery |
| MAX770 |
Step-Up/Step-Down Current Source Charges Batteries |
| MAX770 |
5V Step-Down Converter Has Transformer-Isolated Feedback |
| MAX770 |
Circuit Connection Adds Current-Mode Operation To PFM Boost Converters |
| MAX771 |
Voltage Regulator Converts To Current Source |
| MAX771 |
Circuit Connection Adds Current-Mode Operation To PFM Boost Converters |
| MAX772 |
Circuit Connection Adds Current-Mode Operation To PFM Boost Converters |
| MAX773 |
Switching Regulator/Transformer Steps Down From High Voltage |
| MAX773 |
Simple Circuit Charges Lead-Acid Batteries |
| MAX773 |
Circuit Connection Adds Current-Mode Operation To PFM Boost Converters |
| MAX774 |
Off-The-Shelf Transformer Adapts Controller For SLIC Applications |
| MAX791 (pdf) |
Provide Battery Backup For Pseudo-Static RAMs |
| MAX797 |
Synchronous Buck-Regulator Output Terminates High-Speed Data |
| MAX797 |
Battery Charger Delivers 2.5A With >96% Efficiency |
| MAX800M |
Boost Converter Yields Orderly Shutdown |
| MAX809L |
Switch-Mode Converter Starts With Full Load Connected |
| MAX812 |
Tiny IC Debounces Pushbutton Switch |
| MAX8211 (pdf) |
Load-Disconnect Switch Consumes Only 8µA |
| MAX8212 |
Simple Circuit Disconnects Load From Battery |
| MAX8213 |
5-Comparator IC Provides 3V-To-5V Regulator And µP Reset |
| MAX823 |
Supervisory Circuits Keep Your Microprocessor under Control |
| MAX828 |
Tiny Charge Pump Provides Highly Reliable Low-Cost Solution to Negative Reference Voltage |
| MAX829 |
Voltage-Inverter IC Forms High-Efficiency Rail Splitter |
| MAX835 |
High-Voltage Circuit Breaker Protects To 26V |
| MAX837 |
Tiny Light Sensor With Logic Output Draws Less Than 10µA |
| MAX845 |
LAN Power Supply Generates Isolated 9V |
| MAX845 |
5V Step-Down Converter Has Transformer-Isolated Feedback |
| MAX845 |
Transformer-Driver IC Controls Bidirectional Switch |
| MAX856 |
Switch Allows Low-Voltage Regulator To Start Under Load |
| MAX856 |
Harnessing Solar Power wih Smart Power-Conversion Techniques |
| MAX856 |
Single-Cell Boost Converter Generates Auxiliary Bias For LCD |
| MAX857 |
Autotransformer Boosts Maximum VOUT |
| MAX860 |
5V Supply Derives Power From 3-Wire RS-232 Port |
| MAX863 |
Circuit Connection Adds Current-Mode Operation To PFM Boost Converters |
| MAX865 |
DAC-Powered Charge Pump Varies Negative Rail |
| MAX866 |
Supply Generates 5V From Solar-Cell Power |
| MAX867 |
Boost Controller Drives Buck Converter |
| MAX868 |
Regulated LCD-Bias Generator Requires No Inductor |
| MAX872 |
P-FET Linear Regulator Has Low Dropout Voltage |
| MAX872 |
Battery-Powered Circuit Measures Milli Ohms and Micro Ohms |
| MAX872 |
Linear Regulator Converts 3.3V To 2.9V |
| MAX872 |
PC Printer Port Controls Data Logger |
| MAX873 |
Voltage Reference Compensates Reference Junction |
| MAX881R |
Pulsed Sensor Extends Battery Life |
| MAX882 |
Latching Regulator Prevents Deep Discharge Of Battery |
| MAX8865S |
Battery-Switchover Circuit Accomodates 3V Systems |
| MAX890L |
Current-Limit Switch is Digitally Programmable |
| MAX903 |
Simple Circuit Stretches Pulses |
| MAX912 |
Dual Comparator Forms Temperature-Compensated Proximity Detector |
| MAX921 |
Comparator and Charge Pump Converts 3V to 5V |
| MAX921 |
Simple Circuit Measures Battery Drain |
| MAX921 |
Convert 3V To 5V Without Inductors |
| MAX921 |
Boost Converter Has High Efficiency At Light Loads |
| MAX921 |
Memory-Backup Supply is Simple And Efficient |
| MAX923 |
Low Battery Monitor Delays System Shutdown |
| MAX931 |
Low-Power, 32kHz Oscillator Operates Over Wide Supply Range |
| MAX931 |
Adjustable LNB Power Supply Is DiSEqC Compatible |
| MAX933 |
Circuit Guards Battery Against Polarity Reversal And High Current |
| MAX933 |
Single IC Manages Battery Backup |
| MAX933 |
Pulsed Sensor Extends Battery Life |
| MAX951 |
Low-Power 3V ADC is 0.05% Linear |
| MAX971 |
IR Sensor/Monitor Wakes Host System |
| MAX981 |
Supply Circuitry Selects Main/Backup Voltage And Disconnects |
| MAX985 |
Small Photodiode Receiver Handles Fiber Optic Data Rates To 800kbps |
| MAX988 |
Visible-Laser Driver Has Digitally Controlled Power Modulation |
| MX580 (pdf) |
D/A Converter Generates Multiple Precision Outputs |
| MX7228 (pdf) |
Octal Trimpots Offer Rail-to-Rail Adjustments |
| MX7524 (pdf) |
Voltage-Output D/A Converter Offers Low-Power Operation And Shutdown |
| MX7528 |
Dual, VOUT DAC Consumes Miniscule Power |
| MX7545 (pdf) |
Sample/Hold Has Zero Droop and Infinite Hold |
| Telecom |
App Note 300: Telecom Application Notes Index |
| UCSP |
Wafer-Level Chip-Scale Package |
