Output attenuator
This is required and reduces the output voltage from the cloud charge detector via a resistive chain from the output to earth consisting of two resistors used as a potential divider to ensure that the voltage presented to the ADC-16 does not exceed the +2.5 volt limit.
The resistor chain consists of a 470 kΩ resistor connected to the output of the cloud charge meter in series with a 100 kΩ resistor connected to ground. One channel of the ADC-16 is connected to the junction of the resistors and ground. The voltage at this point with the meter adjusted as suggested will be approximately 1 volt, but will be varying a little depending on the atmospheric conditions and the aerial connected.
Sensitivity
This modification is optional and will depend on the local conditions. It comprises modification to the value of the capacitor C5 (1000 pF) in the feedback loop. This can be reduced to increase the sensitivity of the instrument. In the UK, the value of 56 pF seems to work well for the prevailing conditions, but may need to be higher in areas where thunderstorms are more frequent, or more severe.
Input filter
The third modification may be required to ‘retune’ the filter on the front end to reject 50 Hz rather than the 60 Hz American mains that it is designed for.
Referring to the circuit diagram, C1 and C2 are replaced by 330 pF capacitors, and C3 with a 680 pF capacitor (optimized value: 660 pF). The resistors R1 and R2 are 10 MΩ (optimized value: 9.64 MΩ), and R3 is 4.7 MΩ (optimized value: 4.32 MΩ). Using non-optimal values results in a notch frequency of 48 Hz, this can be optimized by trimming the component values if required.
The formula for calculating the values is :
Fc = 1/2 πRC where Fc is in hertz, R is in ohms, and C is in farads.
Indicator unit
A further modification is the attachment of a window comparator to the output of the device driving a pair of LEDs.
An LM393 may be configured using the circuit shown in the application notes, and is capable of driving a pair of high-efficiency LEDs that will indicate that the conditions are noisier than usual.
The LEDs do not provide any meaningful indication of conditions, but they will tend to draw attention to the fact that there is activity, and will also illuminate in response to spikes on the system when the spike is of too short a duration to drive the meter needle.
I have the LEDs mounted at eye level in the radio shack to draw my attention to the fact that the weather conditions might warrant me disconnecting sensitive equipment from the mains and from antennas. A piezo buzzer may also be attached to the device to provide audible ‘chirps’, but should be fitted with a switch to mute it.
Antenna
The sensitivity of the device will also depend on the antenna that is used for the experiment. The article suggests using a foil ‘pie dish’ but in practice, this was found to be somewhat insensitive, so a 20 foot length of wire was taped in a square spiral to the inside of a window that had been cleaned with alcohol.
Cleaning with alcohol is essential as it removes a slightly conductive surface film that build up with time, and reduces the sensitivity of the device.
Problems have also been encountered where small spiders have anchored webs to the antenna, and in damp conditions, the web has reduced the sensitivity, presumably by providing a slightly conductive path to the local ground.
External antenna
It is perfectly feasible to use an external antenna, however, extreme caution should be exercised as considerable voltages can build up even when there is no apparent electrical activity. If this approach is adopted, a neon bulb may be connected from the antenna to ground to reduce the voltage on the antenna by conducting it to ground, and to indicate that potentially dangerous voltages are present.
Connecting the antenna via a socket will permit experimentation with a variety of configurations. It also allows the antenna to be disconnected to protect the charge detecting device in stormy conditions. The device does not have robust input protection, and it is possible to exceed the limits of the device and destroy it.
In any case, the device should always be disconnected from the ADC-16 when not in use to avoid the risk of applying large voltages to the ADC-16, or the PC motherboard and causing permanent damage.
Power
The device should be powered from a good quality stabilized supply, but can be battery driven if it is to be used in ‘the field’, or away from sources of mains power. If the supply voltage is lower than the nominal 12V suggested, it may be necessary to readjust the offset.
Figure 3: Cloud charge detector circuit