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I've always thought that electronics where expensive and hard but after investing some time learning the basics I made this lil 555 timer PCB and I know there are some things that could be better but I'm really proud of my work submitted by /u/Inside-Ad8295 [link] [comments]

There have been numerous circuits published in EDN as design ideas (DI) for the past few months, centering around the “Flip ON Flop OFF” circuit originally published by Stephen Woodward. These are all designed for DC voltages less than 15 V, since this is the maximum power supply voltage of the CMOS ICs that were used in their design.

Wow the engineering world with your unique design: Design Ideas Submission Guide

There are several applications that use 48 VDC as the supply voltage, such as telecom equipment, solar panel controllers, and EV controllers. In general, DC on/off switches are bulky, as there is no current zero-breaking concept as in the case of AC circuits. A DC on/off switch will break the full load current, leading to arcing and contact erosion. Because of this, bulk-sized switches with higher current capacity are employed.

Figure 1’s circuit can flip on and flop off 48 VDC with a tiny push button. D1 is a 5.6-V Zener diode. It is connected to the base of the Q2 transistor. Its emitter voltage becomes around 5 VDC (Vz-Vbe).

ICs U1 and U2 operate with this 5 VDC voltage. When the pushbutton (PB) is pushed once momentarily, a small pulse is generated, which is counted by U1. Its LSB pin becomes HIGH, which is applied to the gate of Q1. Hence, it conducts, and the output gets 48 VDC. For the next push of PB, the LSB pin of U1 goes LOW, and the gate of Q1 becomes LOW, and Q1 stops conducting. This makes the output voltage go to zero. This action repeats for every push.

Figure 1 The flip on, flop off circuit for 48 V. The output gets 48V DC when you push PB once momentarily. For the next push, output becomes 0 V. U1 and U2 operate at 5VDC only. Connect the Vcc pins of U1 and U2 to VDD and the ground pins to VSS, as shown in the above circuit. Use heat sink for Q1 for higher currents.

Since PB encounters current around a milliamp, the low current, sleek PB is sufficient to switch ON or OFF the 48-V supply with high current. With a proper heatsink on Q1, this circuit can switch ON or OFF DC currents up to several amps as per the data sheet of Q1.

Both R1 and C1 are for PB switch debounce. Both R2 and C2 are for the power-on reset of U1.

If galvanic isolation is needed (this may not always be the case), you may connect an ON/OFF switch prior to the input. In this topology, on-load switching is taken care of by the PB-operated circuit, and the ON/OFF switch switches zero current only, so it does not need to be bulky. You can select a switch that passes the required load current. While switching ON, first close the ON/OFF switch and then operate PB to connect. While switching OFF, first push PB to disconnect and operate the ON/OFF switch.

Jayapal Ramalingam has over three decades of experience in designing electronics systems for power & process industries and is presently a freelance automation consultant.

Related Content

• Flip ON flop OFF
• Latching D-type CMOS power switch: A “Flip ON Flop OFF” alternative
• Flip ON flop OFF without a flip/flop
• Another simple flip ON flop OFF circuit
• Elaborations of yet another Flip-On Flop-Off circuit

The post Flip ON Flop OFF for 48-VDC systems appeared first on EDN.

The Keysight N9048B PXE EMI test receiver, paired with a standalone stream processing unit (SPU), delivers real-time, gapless 1-GHz time domain scan (TDS) bandwidth. With the SPU upgrade, the receiver covers 30 MHz to 1 GHz in a single step—down from three in the previous version—tripling EMI test speed. Together, the units enable faster, more accurate EMI testing.

With 1-GHz FFT bandwidth, the system accelerates EMI scans by covering the CISPR C and D bands in a single pass and supports user-selectable resolution bandwidths of 9 kHz, 120 kHz, and 1 MHz. Real-time, gapless capture ensures no transient events are missed, while high sensitivity and wide dynamic range reveal signals close to the noise floor.

The test setup shortens troubleshooting time from hours to minutes and fully complies with CISPR 16-1-1:2019 requirements. Additionally, the standalone SPU provides a path for future upgrades, offering long-term flexibility.

The Keysight N9048B PXE EMI receiver will be showcased at Techno-Frontier 2025 in Tokyo at the TOYO booth. Learn more about the N9048BSPU stream processing unit by viewing the flyer here.

N9048B PXE product page

Keysight Technologies 

The post 1-GHz TDS upgrade triples EMI test speed appeared first on EDN.