TinyPower TM HT70xxA-2 Voltage Detector Features General Description • Low power consumption The HT70xxA-2 series devices area set of three terminal low power voltage detectors implemented in CMOS technology. Each voltage detector in the series detects a particular fixed voltage ranging from 2.2V to 8.2V. The voltage detectors consist of a high-precision and low power consumption standard voltage source as well as a comparator, hysteresis circuit, and an output driver. CMOS technology ensures low power consumption. • Low temperature coefficient • High input voltage range (up to 30V) • Quiescent current 2.5μA • Output voltage accuracy: tolerance ±1% • Built-in hysteresis characteristic • TO92, SOT89 and SOT23-5 package Although designed primarily as fixed voltage detectors, these devices can be used with external components to detect user specified threshold voltages. Applications • Battery checkers • Level selectors • Power failure detectors • Microcomputer reset • Battery memory backup • Non-volatile RAM signal storage protectors Selection Table Part No. Detectable Voltage Hysteresis Width HT7022A-2 2.2V 0.110V HT7024A-2 2.4V 0.120V HT7027A-2 2.7V 0.135V HT7033A-2 3.3V 0.165V HT7039A-2 3.9V 0.195V HT7044A-2 4.4V 0.220V HT7050A-2 5.0V 0.250V HT7082A-2 8.2V 0.410V Tolerance Package Marking ±1% TO92 SOT89 SOT23-5 70xxA-2 (for TO92) 70xxA-2 (for SOT89) xxA2 (for SOT23-5) Note: ″xx″ stands for detectable voltages. Rev. 1.50 1 May 16, 2016 HT70xxA-2 Block Diagram N Channel Open Drain Output (Normal Open; Active Low) Output Table & Curve V VDD VDD>VDET(+) VDD≤VDET(−) VOUT Hi-Z VSS O U T D a s h lin e ... V S o lid lin e ... V V V D E T V D E T V 1 .0 5 IN IN fro m L fro m H O I H L O I IN H Y S Pin Assignment Rev. 1.50 2 May 16, 2016 HT70xxA-2 Absolute Maximum Ratings Supply Voltage ....................................................VSS−0.3V to VSS+33V Power Consumption.................................................................. 200mW Output Voltage................................................... VSS−0.3V to VDD+0.3V Storage Temperature.................................................... −50°C to 125°C Output Current............................................................................. 50mA Operating Temperature.................................................. −40°C to 85°C Note: These are stress ratings only. Stresses exceeding the range specified under ″Absolute Maximum Ratings″ may cause substantial damage to the device. Functional operation of this device at other conditions beyond those listed in the specification is not implied and prolonged exposure to extreme conditions may affect device reliability. Electrical Characteristics HT7022A-2 Ta=25°C Symbol Parameter Test Conditions VDD Conditions Min. Typ. Max. Unit V VDET Detection Voltage — — 2.178 2.200 2.222 VHYS Hysteresis Width — — 0.02VDET 0.05VDET 0.10VDET V IDD Operating Current 3.2V — 2.5 4.0 µA VDD Operating Voltage 1.5 — 30 V IOL Output Sink Current 1 2 — mA tDELAY No load — — VDET–0.2V VOUT=0.2V Temperature Coefficient — -40°C<Ta<85°C — ±100 — ppm/°C Output Delay Time — RL=100kΩ (see fig 1) — — 200 µs HT7024A-2 Ta=25°C Symbol Parameter Test Conditions VHYS Hysteresis Width — IDD Operating Current 3.4V VDD Operating Voltage IOL Output Sink Current tDELAY Rev. 1.50 Max. Unit — 2.376 2.400 2.424 V — 0.02VDET 0.05VDET 0.10VDET V — 2.5 4.0 µA 1.5 — 30 V 1 2 — mA — Detection Voltage Typ. Conditions VDET Min. VDD No load — — VDET–0.2V VOUT=0.2V Temperature Coefficient — -40°C<Ta<85°C — ±100 — ppm/°C Output Delay Time — RL=100kΩ (see fig 1) — — 200 µs 3 May 16, 2016 HT70xxA-2 HT7027A-2 Symbol Ta=25°C Parameter Test Conditions VDD Conditions Min. Typ. Max. Unit V VDET Detection Voltage — — 2.673 2.700 2.727 VHYS Hysteresis Width — — 0.02VDET 0.05VDET 0.10VDET V IDD Operating Current 3.7V — 2.5 4.0 µA VDD Operating Voltage 1.5 — 30 V IOL Output Sink Current 1 2 — mA tDELAY No load — — VDET–0.2V VOUT=0.2V Temperature Coefficient — -40°C<Ta<85°C — ±100 — ppm/°C Output Delay Time — RL=100kΩ (see fig 1) — — 200 µs HT7033A-2 Symbol Ta=25°C Parameter Test Conditions VDD Conditions Min. Typ. Max. Unit V VDET Detection Voltage — — 3.267 3.300 3.333 VHYS Hysteresis Width — — 0.02VDET 0.05VDET 0.10VDET V IDD Operating Current 4.3V — 2.5 4.0 µA VDD Operating Voltage 1.5 — 30 V IOL Output Sink Current 2 4 — mA tDELAY No load — — VDET–0.2V VOUT=0.25V Temperature Coefficient — -40°C<Ta<85°C — ±100 — ppm/°C Output Delay Time — RL=100kΩ (see fig 1) — — 200 µs HT7039A-2 Symbol Ta=25°C Parameter Test Conditions VDD Conditions Min. Typ. Max. Unit V VDET Detection Voltage — — 3.861 3.900 3.939 VHYS Hysteresis Width — — 0.02VDET 0.05VDET 0.10VDET V IDD Operating Current 4.9V — 2.5 4.0 µA VDD Operating Voltage 1.5 — 30 V IOL Output Sink Current 2 4 — mA tDELAY No load — — VDET–0.2V VOUT=0.25V Temperature Coefficient — -40°C<Ta<85°C — ±100 — ppm/°C Output Delay Time — RL=100kΩ (see fig 1) — — 200 µs HT7044A-2 Symbol Ta=25°C Parameter Test Conditions VDD Conditions VDET Detection Voltage — — VHYS Hysteresis Width — — IDD Operating Current 5.4V VDD Operating Voltage — IOL Output Sink Current tDELAY Rev. 1.50 No load — VDET–0.2V VOUT=0.36V Min. Typ. Max. Unit 4.356 4.400 4.444 V 0.02VDET 0.05VDET 0.10VDET V — 2.5 4.0 1.5 — 30 µA V 4 7 — mA Temperature Coefficient — -40°C<Ta<85°C — ±100 — ppm/°C Output Delay Time — RL=100kΩ (see fig 1) — — 200 µs 4 May 16, 2016 HT70xxA-2 HT7050A-2 Ta=25°C Symbol Test Conditions Parameter VDD Conditions VDET Detection Voltage — — VHYS Hysteresis Width — — IDD Operating Current 6.0V VDD Operating Voltage IOL Output Sink Current tDELAY Typ. Max. Unit 4.950 5.000 5.050 V 0.02VDET 0.05VDET 0.10VDET No load — Min. — VDET–0.2V VOUT=0.36V V — 2.5 4.0 µA 2.1 — 30 V 4 7 — mA Temperature Coefficient — -40°C<Ta<85°C — ±100 — ppm/°C Output Delay Time — RL=100kΩ (see fig 1) — — 200 µs HT7082A-2 Ta=25°C Symbol Test Conditions Parameter VDD Conditions — — VDET Detection Voltage VHYS Hysteresis Width — IDD Operating Current 9.2V VDD Operating Voltage IOL Output Sink Current tDELAY — Typ. Max. Unit 8.118 8.200 8.282 V 0.02VDET 0.05VDET 0.10VDET No load — Min. — VDET–0.2V VOUT=0.36V V — 2.5 4.0 µA 2.1 — 30 V 4 7 — mA Temperature Coefficient — -40°C<Ta<85°C — ±100 — ppm/°C Output Delay Time — RL=100kΩ see fig 1) — — 200 µs VDD VDET VHYS VDD 0.8V RL VOUT HT70xxA-2 VOUT VSS tDELAY Fig 1 Rev. 1.50 5 May 16, 2016 HT70xxA-2 Typical Performance Characteristics Detection Voltage vs Temperature HT7022A-2 Detection Voltage (V) 2.60 Falling Curve 2.50 Rising Curve 2.40 2.30 2.20 2.10 2.00 -40 -30 -20 -10 0 10 20 30 Temperature(OC) 40 50 60 70 80 40 50 60 70 80 40 50 60 70 80 Hysteresis Width vs Temperature HT7022A-2 Hysteresis Width (V) 0.20 0.15 0.10 0.05 0.00 -40 -30 -20 -10 0 10 20 30 Temperature(OC) Operating Current vs Temperature HT7022A-2 Operation Current (uA) 6.00 VDD=3.2V 5.00 4.00 3.00 2.00 1.00 0.00 -40 -30 -20 -10 0 10 20 30 Temperature(OC) Output Sink Current vs Temperature HT7022A-2 Output Sink Current (mA) 6.0 5.0 4.0 3.0 2.0 1.0 0.0 Rev. 1.50 -40 -30 -20 -10 0 10 20 30 Temperature(OC) 6 40 50 60 70 80 May 16, 2016 HT70xxA-2 Functional Description The HT70xxA-2 series is a set of voltage detectors equipped with a high stability voltage reference which is connected to the negative input of a comparator denoted as VREF in the following figure for NMOS output voltage detector. When the voltage drop to the positive input of the comparator (i,e,VB) is higher than VREF, VOUT goes high, M1 turns off, and VB is expressed as VBH=VDD×(RB+RC)/ (RA+RB+RC). If VDD is decreased so that VB falls to a value less than VREF, the comparator output inverts from high to low, VOUT goes low, VC is high, M1 turns on, RC is bypassed, and VB becomes: VBL=VDD×RB/(RA+RB), which is less than VBH. By so doing, the comparator output will stay low to prevent the circuit from oscillating when VB≈VREF. NMOS Output Voltage Detector If VDD falls below the minimum operating voltage, the output becomes undefined. When VDD goes from low to VDD×RB/(RA+RB)>VREF, the comparator output and VOUT goes high. The figure demonstrates the NMOS output type with positive output polarity (VOUT is normally open, active low). Application circuits shown are examples of positive output polarity (normally open, active low) unless otherwise specified. The detectable voltage is defined as: VDET (−) = (RA+RB+RC) / (RB+RC) × VREF The release voltage is defined as: VDET (+) = (RA+RB) / RB × VREF The hysteresis width is: VHYS = VDET (+) − VDET (−) Rev. 1.50 7 May 16, 2016 HT70xxA-2 Application Circuits Microcomputer Reset Circuit Power-on Reset Circuit Normally a reset circuit is required to protect the microcomputer system from malfunctions due to power line interruptions. The following examples show how different output configurations perform a reset function in various systems. With several external components, the NMOS open drain type of the HT70xxA-2 series can be used to perform a power-on reset function as shown: • NMOS open drain output application for separate power supply • NMOS open drain output application with R-C delay Rev. 1.50 8 May 16, 2016 HT70xxA-2 5V Power Line Monitoring Circuit Generally, a minimum operating voltage of 4.5V is guaranteed in a 5V power line system. The HT7044A-2 is recommended for use as 5V power line monitoring circuit. • Varying the detectable voltage with a diode • 5V power line monitor with power-on reset Detectable voltage=Vf1+Vf2+VDET Malfunction Analysis The following circuit demonstrates the way a circuit analyzes malfunctions by monitoring the variation or spike noise of power supply voltage. • with 5V voltage regulator Charge Monitoring Circuit The following circuit shows a charged monitor for protection against battery deterioration by overcharging. When the voltage of the battery is higher than the set detectable voltage, the transistor turns on to bypass the charge current, protecting the battery from overcharging. Change of Detectable Voltage If the required voltage is not found in the standard product selection table, it is possible to change it by using external resistance dividers or diodes. • Varying the detectable voltage with a resistance divider Detectable voltage=(RA+RB)/RB×VDET Hysteresis width=(RA+RB)/RB×VHYS Rev. 1.50 9 May 16, 2016 HT70xxA-2 Level Selector The following diagram illustrates a logic level selector. Rev. 1.50 10 May 16, 2016 HT70xxA-2 Package Information Note that the package information provided here is for consultation purposes only. As this information may be updated at regular intervals users are reminded to consult the Holtek website for the latest version of the Package/ Carton Information. Additional supplementary information with regard to packaging is listed below. Click on the relevant section to be transferred to the relevant website page. • Further Package Information (include Outline Dimensions, Product Tape and Reel Specifications) • Packing Meterials Information • Carton information Rev. 1.50 11 May 16, 2016 HT70xxA-2 3-pin TO92 Outline Dimensions Symbol Nom. Max. A 0.173 0.180 0.205 B 0.170 — 0.210 C 0.500 0.580 — D — 0.015 BSC — E — 0.010 BSC — F — 0.050 BSC — G — 0.035 BSC — H 0.125 0.142 0.165 Symbol Rev. 1.50 Dimensions in inch Min. Dimensions in mm Min. Nom. Max. A 4.39 4.57 5.21 B 4.32 — 5.33 C 12.70 14.73 — D — 0.38 BSC — E — 2.54 BSC — F — 1.27 BSC — G — 0.89 BSC — H 3.18 3.61 4.19 12 May 16, 2016 HT70xxA-2 3-pin SOT89 Outline Dimensions Symbol Dimensions in inch Min. Nom. Max. A 0.173 — 0.181 B 0.053 — 0.072 C 0.090 — 0.102 D 0.035 — 0.047 E 0.155 — 0.167 F 0.014 — 0.019 G 0.017 — 0.022 H — 0.059 BSC — I 0.055 — 0.063 J 0.014 — 0.017 Symbol Rev. 1.50 Dimensions in mm Min. Nom. Max. A 4.40 — 4.60 B 1.35 — 1.83 C 2.29 — 2.60 D 0.89 — 1.20 E 3.94 — 4.25 F 0.36 — 0.48 G 0.44 — 0.56 H — 1.50 BSC — I 1.40 — 1.60 J 0.35 — 0.44 13 May 16, 2016 HT70xxA-2 5-pin SOT23-5 Outline Dimensions H Symbol A Min. Nom. Max. — — 0.057 A1 — — 0.006 A2 0.035 0.045 0.051 b 0.012 — 0.020 C 0.003 — 0.009 D — 0.114 BSC — E — 0.063 BSC — e — 0.037 BSC — e1 — 0.075 BSC — H — 0.110 BSC — L1 — 0.024 BSC — θ 0° — 8° Symbol Rev. 1.50 Dimensions in inch Dimensions in mm Min. Nom. Max. A — — 1.45 A1 — — 0.15 A2 0.90 1.15 1.30 b 0.30 — 0.50 C 0.08 — 0.22 D — 2.90 BSC — E — 1.60 BSC — e — 0.95 BSC — e1 — 1.90 BSC — H — 2.80 BSC — L1 — 0.60 BSC — θ 0° — 8° 14 May 16, 2016 HT70xxA-2 Copyright© 2016 by HOLTEK SEMICONDUCTOR INC. The information appearing in this Data Sheet is believed to be accurate at the time of publication. However, Holtek assumes no responsibility arising from the use of the specifications described. The applications mentioned herein are used solely for the purpose of illustration and Holtek makes no warranty or representation that such applications will be suitable without further modification, nor recommends the use of its products for application that may present a risk to human life due to malfunction or otherwise. Holtek's products are not authorized for use as critical components in life support devices or systems. Holtek reserves the right to alter its products without prior notification. For the most up-to-date information, please visit our web site at http://www.holtek.com.tw. Rev. 1.50 15 May 16, 2016