I wrote in the fraud of energy efficient lighting – e-ballasts of frustration with green measures forced on us, measures that have replaced tried and true reliable lighting solutions with high tech low reliability solutions in a false promise of net energy saving.
Typically, the cost of repair and replacement of this unreliable technology is much greater than their direct energy saving, indeed much greater than their energy consumption of the life of the equipment.
Above is a ballast removed from a light this morning after 4 years during which it was hardly ever used… perhaps 10 hours at most… so the original capital cost of $80 for luminaire and fitting for 10 hours service gives an average cost of $8/hr for capital and about $0.01/hr for energy. Continue reading Another Osram e-ballast bites the dust
There is often a need for a 9V battery for portable test equipment (NNA, Noise Bridge, Low R meter, Power Meter etc). A solution is a 8 cell NiMH pack.
Above, a battery pack made from two Hobbyking 4 low self discharge AA cells. The packs come with JR servo connectors, and the pins are rewired to use the -ve from one pack and +ve from the other pack to one of the JR connectors. The other wires are connected via a 3A Polyswitch for s/c protection. A short JR to 2.1mm DC connector is made from a JR extension cable and 2.1mm connector. Continue reading Inexpensive utility rechargeable 9V battery pack for test instruments
It is a common practice that a Return Loss (RL) measurement of a s/c or o/c line section is used to calculate the Matched Line Loss (MLL) where MLL=RL/2.
This technique might work with low error in lots of cases, but not all… it is flawed. Continue reading On Witt’s calculation of Matched Line Loss from Return Loss
Hams talk at length about baluns but rarely in quantitative terms.
A quotation from Lord Kelvin is most appropriate:
When you can measure what you are speaking about, and express it in numbers, you know something about it. But when you cannot measure it, when you cannot express it in numbers, your knowledge is of a meagre and unsatisfactory kind. It may be the beginning of knowledge but you have scarcely in your thoughts advanced to the state of science. Continue reading Baluns – show me the numbers
The message “ashim at shell servo” must be an important one.
I have heard VK2UBQ-9 sending this message to VK2XSO-5 for many months, a couple of hundred times a day when VK2UBQ-9 has his radio switched on.
The intended recipient was last reported on aprs.fi in May 2014, seven months ago, yet the APRS system is still wasting bandwidth trying to deliver this message, presumably waiting for a delivery acknowledgement. Continue reading ashim at shell servo
I mentioned in Solder cream has a use-by date that a current project is another QRP2000 synthesiser.
Above, the topside of the synthesiser board. The optional output transformer can be seen at lower left. Continue reading QRP2000 synthesiser build
A current project is another QRP2000 synthesiser.
It has about 15 surface mount parts on the board underside, and it was tempting to use solder paste / cream and hot air to solder the parts on… less risk of flicking them on the floor and the self align due to surface tension in the molten solder. Continue reading Solder cream has a use-by date
My recent article Near-field field strength measurements using the RFPM1 described a technique using VK3AQZ’s RF Power Meter which is based on the AD8307 log detector.
There are many ways to measure low level RF power or voltage, and this article describes methods that I have used using a simple diode detector attached to the HF loop, and measuring the DC output voltage using a small digital panel meter with 9V battery for a self contained measurement system with little risk of significant common mode current. Such a system can be hauled to some height and read remotely with a telescope.
Continue reading Near-field field strength measurements using a diode detector
Review of Boswell et al paper “Performance of a small loop antenna in the 3-10 MHz band” discussed measurement of near-field field strength for measurement of performance of a small transmitting loop (STL).
This article describes a method of performing near-field field strength measurements using a portable RF power meter (RFPM1) and a small untuned square loop. Continue reading Near-field field strength measurements using the RFPM1
(Boswell et al 2005) discussed a small transmitting loop (STL) and offered predictions and measurements of performance.
This article is a review of the discussion at 7MHz.
The STL is a 1m diameter circular loop of 22mm diameter copper conductor at 1,5m height over ground with parameters δ=0.005 and ε=10.
Performance is assessed by prediction and measurement of near-field strength.
Above, Figure 6 from (Boswell et al 2005) shows their predictions and measurements of field strength in the near-field at a range of distances at ground level. Continue reading Review of Boswell et al paper “Performance of a small loop antenna in the 3-10 MHz band”