HA17901, HA17339 Series Quadruple Comparators Description The HA17901 and HA17339 series products are comparators designed for use in power or control systems. These IC operate from a single power-supply voltage over a wide range of voltages, and feature a reduced power-supply current since the power-supply voltage is determined independently. These comparators have the unique characteristic of ground being included in the common-mode input voltage range, even when operating from a single-voltage power supply. These products have a wide range of applications, including limit comparators, simple A/D converters, pulse/square-wave/time delay generators, wide range VCO circuits, MOS clock timers, multivibrators, and high-voltage logic gates. Features • • • • • • • • Wide power-supply voltage range: 2 to 36V Extremely low current drain: 0.8mA Low input bias current: 25nA Low input offset current: 5nA Low input offset voltage: 2mV The common-mode input voltage range includes ground. Low output saturation voltage: 1mV (5µA), 70mV (1mA) Output voltages compatible with CMOS logic systems HA17901, HA17339 Series Ordering Information Type No. Application Package HA17901PJ Car use DP-14 HA17901FPJ FP-14DA HA17901FPK FP-14DA HA17901P Industrial use DP-14 HA17901FP HA17339 FP-14DA Commercial use DP-14 HA17339F FP-14DA Pin Arrangement Vout2 1 14 Vout3 Vout1 2 13 Vout4 VCC 3 Vin(–)1 4 11 Vin(+)4 Vin(+)1 5 10 Vin(–)4 Vin(–)2 6 Vin(+)2 7 1 4 – + – + – + 2 + 3– (Top view) 2 12 GND 9 Vin(+)3 8 Vin(–)3 HA17901, HA17339 Series Circuit Structure (1/4) VCC Q2 Vin(+) Q3 Q4 Q1 Vout Q8 Vin(–) Q7 Q5 Q6 3 HA17901, HA17339 Series Absolute Maximum Ratings (Ta = 25°C) Symbol 17901 P 17901 PJ 17901 FP 17901 FPJ 17901 FPK 17339 Item 17339 F Unit Powersupply voltage VCC 36 36 36 36 36 36 36 V Differential input voltage Vin(diff) ±V CC ±V CC ±V CC ±V CC ±V CC ±V CC ±V CC V Input voltage Vin –0.3 to +VCC –0.3 to +VCC –0.3 to +VCC –0.3 to +VCC –0.3 to +VCC –0.3 to +VCC –0.3 to +VCC V Output current Iout*2 20 20 20 20 20 20 20 mA Allowable power dissipation PT 625*1 625*1 625*3 625*3 625*3 625*1 625*3 mW Operating temperature Topr –20 to +75 –40 to +85 –20 to +75 –40 to +85 –40 to +125 –20 to +75 –20 to +75 °C Storage temperature Tstg –55 to +125 –55 to +125 –55 to +125 –55 to +125 –55 to +150 –55 to +125 –55 to +125 °C Output pin voltage Vout 36 36 36 36 36 36 36 V Notes: 1. These are the allowable values up to Ta = 50°C. Derate by 8.3mW/°C above that temperature. 2. These products can be destroyed if the output and VCC are shorted together. The maximum output current is the allowable value for continuous operation. 3. See notes of SOP Package Usage in Reliability section. 4 HA17901, HA17339 Series Electrical Characteristics 1 (VCC = 5V, Ta = 25°C) Item Symbol Min Typ Max Unit Test Condition Input offset voltage VIO — 2 7 mV Output switching point: when VO = 1.4V, RS = 0Ω Input bias current I IB — 25 250 nA I IN(+) or IIN(–) Input offset current I IO — 5 50 nA I IN(+) – IIN(–) Common-mode input voltage* 1 VCM 0 — VCC – 1.5 V Supply current I CC — 0.8 2 mA RL = ∞ AVD — 200 — V/mV RL = 15kΩ tR — 1.3 — µs VRL = 5V, RL = 5.1kΩ Output sink current Iosink 6 16 — mA VIN(–) = 1V, VIN(+) = 0, VO ≤ 1.5V Output saturation voltage VO sat — 200 400 mV VIN(–) = 1V, VIN(+) = 0, Iosink = 3mA Output leakage current I LO — 0.1 — nA VIN(+) = 1V, VIN(–) = 0, VO = 5V Voltage Gain Response time* 2 Notes: 1. Voltages more negative than –0.3V are not allowed for the common-mode input voltage or for either one of the input signal voltages. 2. The stipulated response time is the value for a 100 mV input step voltage that has a 5mV overdrive. Electrical Characteristics 2 (VCC = 5V, Ta = – 41 to + 125°C) Item Symbol Min Typ Max Unit Test Condition Input offset voltage VIO — — 7 mV Output switching point: when VO = 1.4V, RS = 0Ω Input offset current I IO — — 200 nA I IN(-) – I IN(+) Input bias current I IB — — 500 nA Common-mode input voltage* 1 VCM 0 — VCC – 2.0 V Output saturation voltage VO — — 440 mV VIN(–) ≥ 1V, V IN(+) = 0, Iosink ≤ 4mA Output leakage current I LO — 1.0 — µA VIN(–) = 0V, VIN(+) ≥ 1V, V O = 30V Supply current I CC — — 4.0 mA All comparators: RL = ∞, All channels ON Note: sat 1. Voltages more negative than –0.3V are not allowed for the common-mode input voltage or for either one of the input signal voltages. 5 HA17901, HA17339 Series Test Circuits 1. Input offset voltage (VIO), input offset current (IIO), and Input bias current (IIB) test circuit Rf 5k VCC SW1 RS 50 – R 20 k R 20 k RS 50 Rf 5 k VC1 RL 51k VO + 470µ – + SW2 V SW1 On Off On Off Vout VO1 1 V VC1 = 2 CC VO2 VO3 VC2 = 1.4V VO4 SW2 On Off Off On VC2 VIO = | VO1 | 1 + Rf / RS (mV) IIO = | VO2 – VO1 | R(1 + Rf / RS) (nA) IIB = | VO4 – VO3 | 2 · R(1 + Rf / RS) (nA) 2. Output saturation voltage (VO sat) output sink current (Iosink), and common-mode input voltage (VCM) test circuit VCC 50 SW1 1 2 VC1 5k 1.6k SW2 1 2 − + 50 50 4.87k SW3 Item VC1 VOsat 2V VC2 0V VC3 — SW1 1 Iosink 2V VCM 2V 0V –1 to VCC 1.5V — 1 2 VC3 VC2 3. Supply current (ICC) test circuit A + 1V 6 – VCC ICC: RL = ∞ SW2 1 SW3 Unit 1 at V VCC = 5V 3 at VCC = 15V 1 2 mA Switched 3 V between 1 and 2 HA17901, HA17339 Series 4. Voltage gain (AVD) test circuit (RL = 15kΩ) +V VCC 20k Vin 10k 30k 10µ RL 15k + + – VO – 50 20k 50 –V AVD = 20 log VO1 — VO2 VIN1 — VIN2 (dB) 5. Response time (tR) test circuit VCC – RL 5.1k +V Vin VO 50 24k + P.G VR 5k 30k 50 120k SW 12V –V tR: RL = 5.1kΩ, a 100mV input step voltage that has a 5mV overdrive • With VIN not applied, set the switch SW to the off position and adjust VR so that VO is in the vicinity of 1.4V. • Apply VIN and turn the switch SW on. 90% 10% tR 7 HA17901, HA17339 Series Characteristics Curve Input Bias Current vs. Power-Supply Voltage Characteristics Input Bias Current vs. Ambient Temperature Characteristics 60 90 VCC = 5 V Ta = 25°C Input Bias Current IIB (nA) Input Bias Current IIB (nA) 80 70 60 50 40 30 20 50 40 30 20 10 10 0 –55 –35 –15 5 25 45 65 0 85 105 125 20 30 40 Ambient Temperature Ta (°C) Power-Supply Voltage VCC (V) Supply Current vs. Ambient Temperature Characteristics Supply Current vs. Power-Supply Voltage Characteristics 1.6 1.8 VCC = 5 V RL = ∞ 1.4 1.2 1.0 0.8 0.6 0.4 Ta = 25°C RL = ∞ 1.4 Supply Current ICC (mA) 1.6 Supply Current ICC (mA) 10 1.2 1.0 0.8 0.6 0.2 0 –55 –35 –15 5 25 45 65 85 105 125 Ambient Temperature Ta (°C) 8 0 10 20 30 Power-Supply Voltage VCC (V) 40 HA17901, HA17339 Series Output Sink Current vs. Ambient Temperature Characteristics Output Sink Current vs. Power-Supply Voltage Characteristics VCC = 5 V Vin(–) = 1 V Vin(+) = 0 Vout = 1.5 V 40 35 30 25 20 15 10 5 0 –55 –35 –15 5 25 45 65 30 Output Sink Current Iosink (mA) Output Sink Current Iosink (mA) 45 20 15 10 5 0 85 105 125 0 10 20 30 40 Ambient Temperature Ta (°C) Power-Supply Voltage VCC (V) Voltage Gain vs. Ambient Temperature Characteristics Voltage Gain vs. Power-Supply Voltage Characteristics 130 130 VCC = 5 V RL = 15 kΩ 125 Ta = 25°C RL = 15 kΩ 120 120 Voltage Gain AVD (dB) Voltage Gain AVD (dB) 25 115 110 105 100 95 110 100 90 80 90 85 –55 –35 –15 70 5 25 45 65 85 105 125 Ambient Temperature Ta (°C) 0 10 20 30 40 Power-Supply Voltage VCC (V) 9 HA17901, HA17339 Series HA17901 Application Examples The HA17901 houses four independent comparators in a single package, and operates over a wide voltage range at low power from a single-voltage power supply. Since the common-mode input voltage range starts at the ground potential, the HA17901 is particularly suited for single-voltage power supply applications. This section presents several sample HA17901 applications. HA17901 Application Notes 1. Square-Wave Oscillator The circuit shown in figure one has the same structure as a single-voltage power supply astable multivibrator. Figure 2 shows the waveforms generated by this circuit. VCC 100k 75pF VCC 4.3k R – C VCC HA17901 Vout + 100k 100k 100k Figure 1 Square-Wave Oscillator (1) Horizontal: 2 V/div, Vertical: 5 µs/div, VCC = 5 V (2) Horizontal: 5 V/div, Vertical: 5 µs/div, VCC = 15 V Figure 2 Operating Waveforms 10 HA17901, HA17339 Series 2. Pulse Generator The charge and discharge circuits in the circuit from figure 1 are separated by diodes in this circuit. (See figure 3.) This allows the pulse width and the duty cycle to be set independently. Figure 4 shows the waveforms generated by this circuit. VCC R1 1M D1 IS2076 R2 100k D2 IS2076 VCC C – 80pF VCC HA17901 Vout + 1M 1M 1M Figure 3 Pulse Generator Horizontal: 2 V/div, Vertical: 20 µs/div, VCC = 5 V Horizontal: 5 V/div, Vertical: 20 µs/div, VCC = 15 V Figure 4 Operating Waveforms 3. Voltage Controlled Oscillator In the circuit in figure 5, comparator A1 operates as an integrator, A2 operates as a comparator with hysteresis, and A3 operates as the switch that controls the oscillator frequency. If the output Vout1 is at the low level, the A3 output will go to the low level and the A1 inverting input will become a lower level than the A1 noninverting input. The A1 output will integrate this state and its output will increase towards the high level. When the output of the integrator A1 exceeds the level on the comparator A2 inverting input, A2 inverts to the high level and both the output Vout1 and the A3 output go to the high level. This causes the integrator to integrate a negative state, resulting in its output decreasing towards the low level. Then, when the A1 output level becomes lower than the level on the A2 noninverting input, the output Vout1 is once again inverted to the low level. This operation generates a square wave on Vout1 and a triangular wave on Vout2. 11 HA17901, HA17339 Series 100k +VC 10 0.1µ Frequency control voltage input 20k 500p A1 – 100k VCC VCC VCC 3k HA17901 5.1k 0.01µ + VCC A2 HA17901 VCC/2 20k 3k + Output 1 – VCC 50k A3 Output 2 VCC/2 – HA17901 VCC = 30V +250mV < +VC < +50V 700Hz < / < 100kHz + Figure 5 Voltage Controlled Oscillator 4. Basic Comparator The circuit shown in figure 6 is a basic comparator. When the input voltage VIN exceeds the reference voltage VREF, the output goes to the high level. VCC Vin + VREF – 3kΩ Figure 6 Basic Comparator 5. Noninverting Comparator (with Hysteresis) Assuming +VIN is 0V, when VREF is applied to the inverting input, the output will go to the low level (approximately 0V). If the voltage applied to +VIN is gradually increased, the output will go high when the value of the noninverting input, +VIN × R2/(R1 + R2), exceeds +VREF. Next, if +VIN is gradually lowered, Vout will be inverted to the low level once again when the value of the noninverting input, (Vout – V IN) × R1/(R1 + R2), becomes lower than VREF. With the circuit constants shown in figure 7, assuming VCC = 15V and +VREF = 6V, the following formula can be derived, i.e. +VIN × 10M/(5.1M + 10M) > 6V, and Vout will invert from low to high when +VIN is > 9.06V. (Vout – VIN) × R1 + VIN < 6V R1 + R2 (Assuming Vout = 15V) When +VIN is lowered, the output will invert from high to low when +VIN < 1.41V. Therefore this circuit has a hysteresis of 7.65V. Figure 8 shows the input characteristics. 12 HA17901, HA17339 Series VCC +VREF 3k – HA17901 + R1 +Vin VCC Vout 5.1M 10M R2 Figure 7 Noninverting Comparator Output Voltage Vout (V) 20 VCC = 15 V, +VREF = 6 V +Vin = 0 to 10 V 16 12 8 4 0 0 5 10 15 Input Voltage VIN (V) Figure 8 Noninverting Comparator I/O Transfer Characteristics 6. Inverting Comparator (with Hysteresis) In this circuit, the output Vout inverts from high to low when +VIN > (VCC + Vout)/3. Similarly, the output Vout inverts from low to high when +V IN < VCC/3. With the circuit constants shown in figure 9, assuming VCC = 15V and Vout = 15V, this circuit will have a 5V hysteresis. Figure 10 shows the I/O characteristics for the circuit in figure 9. VCC +Vin VCC – VCC 3k HA17901 1M Vout + 1M 1M Figure 9 Inverting Comparator 13 HA17901, HA17339 Series Output Voltage Vout (V) 20 VCC = 15 V 16 12 8 4 0 0 5 10 15 Input Voltage VIN (V) Figure 10 Inverting Comparator I/O Transfer Characteristics 7. Zero-Cross Detector (Single-Voltage Power Supply) In this circuit, the noninverting input will essentially beheld at the potential determined by dividing VCC with 100kΩ and 10kΩ resistors. When VIN is 0V or higher, the output will be low, and when VIN is negative, Vout will invert to the high level. (See figure 11.) VCC Vin 5.1k 100k 5.1k 100k VCC – 1S2076 HA17901 + 10k 20M Figure 11 Zero-Cross Detector 14 5.1k Vout HA17901, HA17339 Series Package Dimensions Unit: mm 19.20 20.32 Max 8 6.30 7.40 Max 14 1.30 7 2.54 ± 0.25 0.48 ± 0.10 0.51 Min 2.39 Max 7.62 2.54 Min 5.06 Max 1 + 0.10 0.25 – 0.05 0° – 15° Hitachi Code JEDEC EIAJ Mass (reference value) DP-14 Conforms Conforms 0.97 g Unit: mm 10.06 10.5 Max 8 5.5 14 1 0.10 ± 0.10 1.42 Max 1.27 *0.42 ± 0.08 0.40 ± 0.06 *0.22 ± 0.05 0.20 ± 0.04 2.20 Max 7 + 0.20 7.80 – 0.30 1.15 0° – 8° 0.70 ± 0.20 0.15 0.12 M *Dimension including the plating thickness Base material dimension Hitachi Code JEDEC EIAJ Mass (reference value) FP-14DA — Conforms 0.23 g 15 HA17901, HA17339 Series Cautions 1. Hitachi neither warrants nor grants licenses of any rights of Hitachi’s or any third party’s patent, copyright, trademark, or other intellectual property rights for information contained in this document. Hitachi bears no responsibility for problems that may arise with third party’s rights, including intellectual property rights, in connection with use of the information contained in this document. 2. Products and product specifications may be subject to change without notice. Confirm that you have received the latest product standards or specifications before final design, purchase or use. 3. Hitachi makes every attempt to ensure that its products are of high quality and reliability. However, contact Hitachi’s sales office before using the product in an application that demands especially high quality and reliability or where its failure or malfunction may directly threaten human life or cause risk of bodily injury, such as aerospace, aeronautics, nuclear power, combustion control, transportation, traffic, safety equipment or medical equipment for life support. 4. Design your application so that the product is used within the ranges guaranteed by Hitachi particularly for maximum rating, operating supply voltage range, heat radiation characteristics, installation conditions and other characteristics. Hitachi bears no responsibility for failure or damage when used beyond the guaranteed ranges. Even within the guaranteed ranges, consider normally foreseeable failure rates or failure modes in semiconductor devices and employ systemic measures such as failsafes, so that the equipment incorporating Hitachi product does not cause bodily injury, fire or other consequential damage due to operation of the Hitachi product. 5. This product is not designed to be radiation resistant. 6. No one is permitted to reproduce or duplicate, in any form, the whole or part of this document without written approval from Hitachi. 7. Contact Hitachi’s sales office for any questions regarding this document or Hitachi semiconductor products. Hitachi, Ltd. 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Ltd. 16 Collyer Quay #20-00 Hitachi Tower Singapore 049318 Tel: 535-2100 Fax: 535-1533 Hitachi Asia Ltd. Taipei Branch Office 3F, Hung Kuo Building. No.167, Tun-Hwa North Road, Taipei (105) Tel: <886> (2) 2718-3666 Fax: <886> (2) 2718-8180 Hitachi Asia (Hong Kong) Ltd. Group III (Electronic Components) 7/F., North Tower, World Finance Centre, Harbour City, Canton Road, Tsim Sha Tsui, Kowloon, Hong Kong Tel: <852> (2) 735 9218 Fax: <852> (2) 730 0281 Telex: 40815 HITEC HX Copyright ' Hitachi, Ltd., 1998. All rights reserved. Printed in Japan. 16