Overview
The MC14001BDR2 is a Quad 2-Input NOR Gate from ON Semiconductor, part of the B-Suffix Series CMOS Gates. These devices are constructed with P and N channel enhancement mode devices in a single monolithic structure (Complementary MOS), making them ideal for applications requiring low power dissipation and high noise immunity.
The MC14001BDR2 is packaged in a SOIC-14 (D Suffix) case and is available in tape and reel packaging, making it suitable for high-volume production. This device is Pb-free and RoHS compliant, ensuring environmental sustainability.
Key Specifications
| Parameter | Value | Unit |
|---|---|---|
| DC Supply Voltage Range | -0.5 to +18.0 | V |
| Input or Output Voltage Range (DC or Transient) | -0.5 to VDD + 0.5 | V |
| Input or Output Current (DC or Transient) per Pin | ±10 | mA |
| Power Dissipation, per Package | 500 | mW |
| Ambient Temperature Range | -55 to +125 | °C |
| Storage Temperature Range | -65 to +150 | °C |
| Lead Temperature (8-Second Soldering) | 260 | °C |
| ESD Withstand Voltage (Human Body Model) | > 3000 | V |
| ESD Withstand Voltage (Machine Model) | > 300 | V |
| Output Voltage “0” Level (VOL) | 0.05 | V |
| Output Voltage “1” Level (VOH) | 4.95 to 14.95 | V |
| Propagation Delay Time (tPLH, tPHL) | (0.90 ns/pF) CL + 80 ns to (0.26 ns/pF) CL + 27 ns | ns |
Key Features
- Supply Voltage Range: 3.0 Vdc to 18 Vdc, making it versatile for various applications.
- All Outputs Buffered: Ensures stable output signals.
- Low Power Dissipation: Ideal for applications where power efficiency is crucial.
- High Noise Immunity: Provides reliable operation in noisy environments.
- Capable of Driving TTL Loads: Can drive two low-power TTL loads or one low-power Schottky TTL load over the rated temperature range.
- Input Protection: Double diode protection on all inputs except for triple diode protection on MC14011B and MC14081B.
- Pin-for-Pin Replacements: Compatible with corresponding CD4000 Series B Suffix devices.
- AEC-Q100 Qualified and PPAP Capable: Suitable for automotive and other applications requiring unique site and control change requirements.
- Pb-Free and RoHS Compliant: Environmentally friendly packaging.
Applications
- Digital Logic Circuits: Used in various digital logic circuits where NOR gate functionality is required.
- Automotive Electronics: AEC-Q100 qualified, making it suitable for automotive applications.
- Industrial Control Systems: High noise immunity makes it reliable in industrial environments.
- Consumer Electronics: Low power dissipation is beneficial in battery-powered devices.
- Communication Systems: Can be used in communication systems requiring stable and efficient logic gates.
Q & A
- What is the supply voltage range of the MC14001BDR2?
The supply voltage range is from 3.0 Vdc to 18 Vdc.
- What type of protection does the MC14001BDR2 have on its inputs?
The device has double diode protection on all inputs, except for the MC14011B and MC14081B which have triple diode protection.
- Can the MC14001BDR2 drive TTL loads?
Yes, it can drive two low-power TTL loads or one low-power Schottky TTL load over the rated temperature range.
- What is the maximum output current per pin for the MC14001BDR2?
The maximum output current per pin is ±10 mA.
- Is the MC14001BDR2 Pb-free and RoHS compliant?
Yes, it is Pb-free and RoHS compliant.
- What is the ambient temperature range for the MC14001BDR2?
The ambient temperature range is from -55°C to +125°C.
- What is the propagation delay time for the MC14001BDR2?
The propagation delay time ranges from (0.90 ns/pF) CL + 80 ns to (0.26 ns/pF) CL + 27 ns.
- Can the MC14001BDR2 be used in automotive applications?
Yes, it is AEC-Q100 qualified and PPAP capable, making it suitable for automotive applications.
- What type of packaging is available for the MC14001BDR2?
The device is available in SOIC-14 (D Suffix) packaging and can be shipped in tape and reel format.
- How should unused inputs and outputs be handled on the MC14001BDR2?
Unused inputs must be tied to an appropriate logic voltage level (either VSS or VDD), and unused outputs must be left open.
