Monthly Archives May 2009

VistaCruise Throttle Lock

The VistaCruise is an aftermarket throttle lock, allowing the driver to free up the right hand from time to time. It’s a big help on long hauls when your palm becomes compressed or pinched from squeezing the grip for so long, when your hand is sweaty, or you just want to rest your throttle hand for a minute. It also helps in the winter when you need to switch hand you’re sitting on from time to time to thaw it out 🙂 .

[bullet] Above is a good shot of the completed installation of the modified VistaCruise. You’ll see the black collar on the grip, the little chrome strap is the friction ring, the thumb latch that is used to lock the throttle, a black bar that reaches across the control head (where the kill switch is located), and the 1″ handlebar clamp located between the mirror bracket and control head. The VistaCruise is just above the starter button, so that’s no interference there.

[bullet]The VistaCruise is designed to work with stock grips, or those with a straight (non-contoured) grip body. I recently installed a set of Kuryakin IsoGrips and found that the VistaCruise wouldn’t work with them. The IsoGrips have rubber pads along their length, and they have a flared flange on the end where the VistaCruise collar would normally be installed.

[bullet]The basic installation instructions that come with the VistaCruise are usable, with the exception of modifications to these items:

  • The black collar that slips over the grips: Orient it so that the edge with the setscrews is facing the end of the handlebar (opposite from the usual installation direction, I think). Back the set screws out so that they are not exposed inside of the collar. Using a dremel tool with the little drum sander attachment, bevel the inner diameter of the collar on the side that will be next to the control head (opposite the edge where the setscrews are located). Remove enough material so that it will easily slip over the flared portion of the grip and up against the control head.
  • Using an exacto knife, cut the thin rubber insert to about half it’s thickness (not width!).This is inserted inside of the collar AFTER the collar is slipped over the grip in the next step below. The supplied rubber insert is too thick to be installed between the collar and the Kuryakin IsoGrips.
  • Slip the collar over the grip without the rubber insert in place, and insert the rubber after the ring is pressed all the way against the control head. Run the set screws in until they are flush with the outside surface of the collar.
  • Install the 1″ handlebar clamp between the mirror and control head (you’ll have to loosen the mirror mount and slip it up the bars a little). Cut 1/8″ of length from the end of the black bar that connects between the handlebar clamp and the chrome friction ring/thumb lever assembly.
  • Complete assembly and adjust the rest per the supplied instructions. It looks cool, doesn’t detract much from the looks of the grips, and works great.

[bullet] Here is a shot from in front of the scoot, looking at the black throttle grip collar and chrome friction ring. You’ll also notice the black 1″ handlebar clamp installed between the mirror and the control head. You can see this neat little accessory at the Scootworks website on their Miscellaneous Parts Page at .


KnowledgeQuest – Resistors

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The resistor is probably the most common and well-known of all electrical components. Their uses are many, they are used to drop voltage, limit current, attenuate signals, act as heaters, act as fuses, furnish electrical loads, and divide voltages.

These uses are basic, for example, the voltage divider used is used in a variety of networks to divide voltages in specified increments of the applied voltage such as for analog-to-digital converters and digital-to-analog converters. They are used as matched pairs with relative accuracy much greater than their absolute accuracy. Matching is used in building voltage dividers and Wheatstone & Kelvin Bridges with extremely precise accuracy over a wide range of temperatures. This is done by matching the absolute value and the temperature coefficient of Resistance (TCR). This accuracy is limited only by the ability to accurately measure them and their stability.

There are numerous varieties of resistors. There are Precision Wirewound., NIST Standards, Power Wirewound, Fuse Resistors, Carbon Composition, Carbon Film, Metal Film, Foil, Filament Wound, , and Power Film Resistors. Each of these resistors has a useful purpose.

Resistors have numerous characteristics which determine their accuracy when used. Each will affect the accuracy to a greater or lesser extent depending on the application. Some of these characteristics are Tolerance at DC, Temperature Coefficient of Resistance (TCR), Frequency Response, Voltage Coefficient, Noise, Stability with Time and Load, Temperature Rating, Power Rating, Physical Size, Mounting Characteristics, Thermocouple Effect, and Reliability.

I will go into further detail on the type of resistor, characteristics, and materials to manufacture them in future articles. Most of my experience has been in the design and manufacture of Bridges, Networks, Precision Wirewound, Metal Clad Power, and Power Wirewound. These will be covered in greater detail..

These articles are intended to be general in nature. I would recommend that the appropriate manufacturer be consulted for specific characteristics on the resistors that they manufacture. Each manufacturer will have a specific group of characteristics in which they excel.


 Resistor Tolerance

Resistor Tolerance is expressed as the deviation from nominal value in percent and is measured at 25oC only with no appreciable load applied. It will change depending on the other conditions when in use. For example, a 100 ohm resistor with a tolerance of 10% can range in value from 90 ohms to 110 ohms and this will change as power is applied and the temperature varies.

 Temperature Coefficient of Resistance

The Temperature Coefficient of Resistance (TCR) is expressed as the change in resistance in ppm ( .0001%) with each degree of change in temperature Celsius (Co). This change is not linear with the TCR the lowest at +25oC and increasing as the temperature increases ( or decreases). It can be either a bell-shaped curve or an S-shaped curve. It is treated as being linear unless very accurate measurements are needed, then a temperature correction chart is used. Normally a resistor with a TCR of 100 ppm will change 0.1% over a 10-degree change and 1% over a 100-degree change. The expression of ppm, one part in a million is similar to percent or 1 part in 100 (or percentile)

 Frequency Response

Frequency Response is the change in resistance with changes in frequency and is more difficult to measure. Where exact values are needed, these changes can be plotted but not very accurately, and normally in db change. These measurements can be made with a Boonton RX Meter which is designed for measuring low Q circuits.


Noise levels are measured with very specialized equipment. It is extremely difficult to measure accurately and does not affect the value of the resistor but can have a devastating effect on low signals, digital amplifiers, high gain amplifiers, and other applications sensitive to noise. The best approach is to use resistor types with low or no noise in applications that are sensitive to noise.

 Voltage Coefficient

The Voltage Coefficient is the change in resistance with applied voltage and is associated with Carbon Composition Resistors and Carbon Film Resistors. It is a function of value and the composition of the carbon mixture used in the manufacture of these resistors. This is entirely different and in addition to the effects of self-heating when power is applied.

 Thermocouple Effect

The Thermocouple Effect is due to the Thermal emf generated by the change in the temperature at the junction of two dissimilar metals. This emf is due to the materials used in the leads or in the case of Wirewound Resistors the resistive element also. This can be minimized by keeping both leads at the same temperature. The thermal emf is the result of the difference in the temperature of one lead to the other lead. One lead will cause a positive emf and the opposite lead will generate a negative emf ( or visa versa). When both leads are at the same temperature, the emf’s generated will cancel each other and the same is true where the resistive element joins the leads. Resistors with nickel leads as used in certain welded module applications will generate the highest thermal emf. The resistive element (the wire) of wire wound resistors is designed with a low thermal emf, but some of the wire used for high TCR resistors will have a much larger thermal emf.


Stability is the change in resistance with time at a specific load, humidity level, stress, and ambient temperature. The lower the load and the closer to +25oC the resistor is maintained, the better the stability. Humidity will cause the insulation of the resistor to swell applying pressure (stress) to the resistive element causing a change. Changes in temperature alternately apply and relieve stresses on the resistive element thus causing changes in resistance. The wider the temperature changes and the more rapid these changes are, the greater the change in resistance. If severe enough, it can literally destroy the resistor. Rapidly and continuously subjecting a device to its lowest and highest operating temperatures(called a Thermocycle Test) is considered a destructive test.


Reliability is the degree of probability that a resistor (or any other device) will perform its desired function. There are two ways of defining Reliability. One is the Mean Time Between Failures (MTBF) and the other is the Failure Rate per 1,000 hours of operation. Both of these means of evaluating reliability must be determined with a specific group of tests and a definition of what is the end of life for a device, such as a maximum change in resistance or a catastrophic failure (short or open). Various statistical studies are used to arrive at these failure rates and large samples are tested at the maximum rated temperature with rated load for up to 10,000 hours (24 hrs per day for approximately 13 months).

 Temperature Rating

Temperature rating is the maximum allowable temperature that the resistor may be used. There are generally two temperatures for example, a resistor may be rated at full load up to +85oC derated to no load at +145oC. This means that with certain allowable changes in resistance over life, the resistor may be operated at +85oC with its rated power. It also may be operated with temperatures in excess of +85oC if the load is reduced, but in no case should the temperature exceed the design temperature of +145oC with a combination of ambient temperature and self-heating due to the applied load. A word of caution, some rated loads are at +25oC and must be derated if the ambient temperature exceeds +25oC.

 Power Rating

Power ratings are based on physical size and allowable change in resistance over life. thermal conductivity of materials, insulating and resistive materials, and ambient operating conditions. Again note that all resistors are not rated alike. The safest bet is to use the largest physical size and never use it at its maximum ratings both in temperature and power unless you are prepared to accept the maximum allowable changes in resistance in life. Another thing to note; the majority of change under those conditions will occur during the first 100 hours of operation.

It is important that all of the above characteristics be considered when selecting a particular style and tolerance for each application.



Resistors are available in almost any size ranging from 0.065 inches in diameter by .125 inches long to 12 inches in Diameter to several feet high (for very high voltage resistors). They come in almost any shape that is imaginable. The most common form is cylindrical with leads coming out either end. They can be manufactured in custom shapes to fit the available space when quantities justify.


Resistors can be made with almost any type of mounting. If the need arises, special mountings can be designed to fit the customer’s needs. Some of the more common means of mountings are listed below. The term “Leads” is used in the general sense as a means of connecting the resistor. They may be lugs, wire leads, pins, or any means of connecting the resistor to the circuit.

 Surface Mount

Resistors are available in a surface mounting configuration. This is generally associated with chip resistors that are mounted by solder reflow techniques. This consists of a resistive element of a flat ceramic substrate (or a cylindrical ceramic core) with a solder pad on each end. Sizes range from .163 inches in diameter to .555 inches long cylindrical to a .020 high by .031 wide by .062 long chip.

 Fuse Clip Mounting.

The fuse clip type is made such that it will mount directly into a fuse clip. Fuse resistors are sometimes made like this.

 Single Inline Packaging (SIP)

The Single Inline Package is normally associated with resistor networks consisting of several resistors in the same package. It is a rectangular flat-shaped package with several leads coming out of one surface generally a narrow, long surface.

 Dual Inline Package (DIP)

The Dual Inline Package is again normally associated with resistor networks. The main difference is that leads extend out both narrow, long surfaces and are formed to either flush mount on a PC Board or through-hole mount on a PC board.

 Flat Packs

The Flat Pack is roughly the same as Dual Inline Packaging except the leads come straight out and are not formed for surface mounting or thru-hole mounting. This is just a variation of DIP mounting.

Axial Leads – Axial Lead mounting is what most of us are familiar with using. It consists of a cylindrical (or rectangular or any shape body) with the leads extending out either end parallel to the resistor’s major axis.

 Radial Leads

Radial Lead mounting is similar to Axial Lead mounting except the lead comes out of the body perpendicular to its major axis.

 PC Mounting

PC mounting consists of both leads of the resistor coming out the same surface so that it is easier to mount a resistor (or any other device) vertically. The resistor may be rectangular or cylindrical.

 4 Terminal Mounting

Most styles will offer a 4 terminal means of mounting for low values. This is important when the leads become a significant part of the value. This establishes the point on the leads where the value in within the desired tolerance. It is fixed and prevents changes in the value due to mounting variations.



The Precision Wirewound is a highly accurate resistor with a very low TCR and can be accurate within .005%. A temperature coefficient of resistance (TCR) of as little as 3 parts per million per degree Celsius (3ppm/oC) can be achieved. However, these components are too expensive for general use and are normally used in highly accurate DC applications. The frequency response of this type is not good. When used in an rf application all Precision Wirewound Resistors will have a low Q resonant frequency. The power handling capability is very small. These are generally used in highly accurate DC measuring equipment, and reference resistors for voltage regulators and decoding networks.

The accuracy is maintained at 25oC(degrees Celsius) and will change with temperature. The maximum value available is dependent upon physical size and is much lower than most other types of resistors. Their power rating is approximately 1/10 of a similar physical size in a carbon composition. They are rated for operation at +85oC or +125oC with a maximum operating temperature not to exceed +145oC. This means that full-rated power can be applied at +85 ( 125) oC with no degradation in performance. It may be operated above +125 (85) oC if the load is reduced. The derating is linear, rated load at +125(85) oC and no load at +145oC. Life is generally rated for 10,000 hours at rated temperature and rated load. The allowable change in resistance under these conditions is 0.10%. Extended life can be achieved if operated at lower temperatures and reduced power levels. End-of-life requirements are generally defined by the manufacturer or in some cases by user specification. Some degradation in performance can be expected. In some cases, particularly if the tolerance is very low and the TC is low, the rated power is reduced to improve resistor stability through life. Precision Resistors regardless of type, are designed for maximum accuracy and not to carry power. The materials used in these resistors are highly stable heat-treated materials that do change under extended heat and mechanical stress. The manufacturing processes are designed to remove any stresses induced during manufacture.

There is little detectable noise in this type of resistor. The stability and reliability of these resistors is very good and their accuracy can be enhanced by matching the absolute value and the temperature coefficient over their operating range to achieve very accurate voltage division.


The NIST (National Institute of Standards and Technology) Standard can be as accurate as .001% with roughly the same TCR as Precision Wirewound Resistors and is very stable. These are used as a standard in verifying the accuracy of resistive measuring devices. They are normally the Primary Standards of a company’s test lab.

They are returned to the NIST for measurement and their accuracy is tracked throughout the standard’s life to determine the Standard’s stability. Most companies will have two sets of standards so that they can continue to measure while one set of standards is being measured by the NIST. They will alternate returning these NIST Standards to the NIST, one set one year and the other set the next year. For extremely accurate measurements, the Standard with the longest history and the best stability will be used. If erratic readings are received from the NIST over a period of years, the Standard is retired. Also, if the reading has significantly changed since the last NIST reading, the standard is suspect and all measurements made using that standard must be checked.

Normally, a standard will take about 3 years to stabilize and becomes more stable with time unless it has had excessive power applied or has been dropped. These standards are generally stored in an oil bath at +25oC. During measurement, a thermometer is placed in a cavity in the top of the Standard, called the oil well, and the temperature is recorded for each measurement so that the exact value can be determined. That is the value at +25oC plus or minus the change in value caused by the temperature coefficient. Each standard will have a temperature correction chart for exact values. Being stored in the oil bath prevents the Standard from being stressed by changes in room temperature. These are highly precise devices and are expensive to buy and expensive to maintain, but they are the primary resistor reference for any test lab.

These resistors are furnished in a totally enclosed metal case and for values above 1 ohm, this enclosure is filled with mineral oil (another type of oil may contain additives that can cause corrosion in later life). The values below 1 ohm may be built in an enclosure that is perforated and these must be submersed in oil. If power is applied without it being submersed, the Standard will be ruined.

All NIST Type Standards are equipped with provisions for two-, three-, or four-terminal measurements. The applied power is calculated and the temperature of the Standard is monitored during the test. The lowest power level consistent with sufficient resolution to get the desired measurement is used (in the area of 0.01 watts) and any appreciable rise in temperature will dictate that the measurement should be suspended and the test set-up reviewed for ways to reduce the power level. These Standards are rated for operation at room temperature only but their other characteristics are the same as Precision Wirewound Resistors.


Power Wirewound Resistors are used when it is necessary to handle a lot of power. They will handle more power per unit volume than any other resistor. Some of these resistors are free wound similar to heater elements. These require some form of cooling in order to handle any appreciable amount of power. Some are cooled by fans and others are immersed in various types of liquid ranging from mineral oil to high-density silicone liquids. Most are wound in some type of winding form. These winding forms vary. Some examples are ceramic tubes, ceramic rods, heavily anodized aluminum, fiberglass mandrels, etc.

To achieve the maximum power rating in the smallest package size, the core on which the windings are made must have a material with high heat conductivity. It may be Steatite, Alumina, Beryllium Oxide, or in some cases hard anodized Aluminum. Theoretically, the anodized Aluminum core has better heat conductivity than any other insulated material, with Beryllium Oxide being very close. There are specific problems with the anodized aluminum cores such as nicks in the coating, abrasion during capping, and controlling the anodized thickness. There are various shapes, oval, flat, and cylindrical, and most shapes are designed to optimize heat dissipation. The more heat that can be radiated from the resistor, the more power that can be safely applied.

There is a group of these called “Chassis Mounted Resistors”. These are generally cylindrical power resistors wound on a ceramic core molded and pressed into an aluminum heat sink usually with heat-radiating fins. These are designed to be mounted to metal plates or a chassis to further conduct heat. This results in a rating approximately 5 times or more than its normal rating.

These resistors come in a variety of accuracy and TCRs. They can be custom-made as a crossbreed between a Precision Resistor and a Power Resistor; capable of handling more power than the standard Precision Wirewound but not as accurate. Practically speaking, tolerances of 1% and temperature coefficients of 20 ppm can be achieved on all except the parts that are coated with Vitreous Enamel and low values. The curing process for Vitreous (a type of glass) requires extremely high heat and shrink applying pressure to the winding. This particular group normally will run tolerances of 10% with a TCR of 100ppm/oC. Power Resistors come in a variety of ratings. Most are rated at +25oC and derated linearly to either +275oC or +350oC. Again if the ambient temperature of operation is +275oC, no power can be applied and at +125ooC 1/2 rated power can be applied.

These power ratings are based on mounting the resistor in free air with the leads terminated at the recommended point. On axial lead components, this is 3/8 of an inch from the body. If they can be mounted closer, the resistor will run cooler or you can apply slightly more power and if mounted further out, you must reduce the power. CAUTION, if mounted directly over and in contact with a printed circuit board, the heat from the resistor can charge the board if full power is applied. I don’t know of any PC Boards that are rated at +275oC.

Other means of increasing the amount of power you can apply

    • (a) bond the resistor to the chassis or other metal parts

      [bullet] (b) mount vertically to get the chimney effect (this is very helpful when using those wound ceramic tubes)

      [bullet] (c) terminate as close to the body as practical

      [bullet] (d) submerse in oil (CAUTION some types of resistor coating, particularly silicone-based coatings will disintegrate when immersed in oil and heated). This will increase the rating as much as 5 times. or reduce the temperature rise of the resistor due to self-heating.

The small power resistor can serve a twofold purpose, that is to fulfill its purpose as a resistor and act as a heater in an enclosure. Some users have used them in crystal ovens to maintain the crystal at the desired temperature. It makes a reasonably cheap off-the-shelf heater that comes in a variety of wattages, sizes, and values.

One unique type of power resistor is the “Bathtub Boat Type”. This consists of a resistance wire wound on a fiberglass cord. This is a continuously wound strip, cut into strips of the appropriate length with leads crimped. These resistive elements are placed in a ceramic shell (boat) and a highly filled cement is used to fasten these in the boat. The filler often used in cement is a ceramic material with high heat conductivity. These are very inexpensive, no effort is made to achieve tight tolerances, and low TCRs, and the range of values is extremely limited. They are often found as surge resistors in TVs and other electronic /electrical equipment. Their main selling point is low cost. They are often sold with an enamel coating for a low-power precision wire-wound resistor that is even lower in cost.

One more item to consider, Power Wirewounds are made using alloys with melt temperatures ranging from +1200o C to +1500o C and may be operated cherry red without failure for short periods of time, however the resistance value and TCR will change significantly and the insulating material will severely degrade. The bathtub boat type can not be subjected to this type of overload, the fiberglass winding form will disintegrate.


Fuse Resistors serve a dual purpose, a resistor and a fuse. They are designed so that they will open with a large surge current. The fusing current is calculated based on the amount of energy required to melt the resistive material (the melt temperature plus the amount of energy required to vaporize the resistive material).

These resistors will normally run hotter than a normal precision or power resistor so that a momentary surge will bring the resistive element up to fusing temperature. Some designs create a hot spot inside the resistor to assist in this fusing. Calculations are made and samples are produced to verify the calculations. The major unknown is the heat transfer of the materials, which can be quite significant for pulse of long duration, and is very difficult to calculate.

Mounting of these devices is critical because it will affect the fusing current. These are quite often made to mount in fuse clips for more accurate fusing characteristics.


Carbon composition resistors were once the most common resistors on the market. They still have a very large market and prices are highly competitive. They are made from carbon rods cut in the appropriate length then molded with leads attached. The mix of the carbon can be varied to change the resistivity for the desired values.

High values are much more readily available. Very low values are more difficult to achieve. A 5% tolerance is available. This is usually done by measuring and selecting values. Normal tolerances without measurement and selection is in the area of 20%.

The temperature coefficient of resistance is in the range of 1000 ppm/oC and is negative, that is when the temperature goes up the resistance goes down, and when the temperature goes down, the resistance goes up. This is due to the carbon particles being relaxed (with an increase in temperature) and being compressed (with the reduction in temperature).

These resistors also have a voltage coefficient. That is the resistance will change with applied voltage, the greater the voltage, the greater the change. In addition to a power rating, they also have a voltage rating. (The wire-wound voltage rating is determined by the value and the wattage rating). The voltage rating of Carbon Composition Resistors is determined by physical size as well as the value and wattage rating.

One more item to consider is that due to their construction, they generate noise and this noise level varies with value and physical size. The power capability in relation to physical size is greater than Precision Wirewounds but less than Power Wirewounds.


Carbon Film Resistors have many of the same characteristics as carbon composition resistors. The material is similar therefore they have noise, and a voltage coefficient, the TCR can be much lower because the formula can be varied to achieve this, and the tolerance is much tighter due to the difference in manufacturing processes.

The Carbon Film Resistor is made by coating ceramic rods with a mixture of carbon materials. This material is applied to these rods in a variety of means, the ones most familiar to me are dipping, rolling, printing, or spraying the rods in the appropriate solution. The thickness of the coating can be determined by the viscosity of the solution. This as well as the material composition will determine the ohms/square. Some of you may not be familiar with this term. It simply means that if a material has a resistivity of 100 ohms/square, one square inch with have the same resistance as 1 square mm, or 1 square foot or 1 square yard or 1 square mile all equaling 100 ohms but the power handling capability is proportional to the size.

One batch of material can produce resistors in a wide range of values. These rods are cut to the length required for a specific size of the resistor. These rods can then be spiral cut to a wide range of values. The original method of spiraling these was done with grinding wheels on a machine similar to a lathe. I am sure that later processes use lasers that are programmed to cut to specific values. The maximum ohmic value of this group is the highest in the discrete resistor group.

A tolerance of 1% can be achieved without measuring and selecting. Tolerance of less than 1% can be achieved by measuring and selecting. You should use caution in getting tight tolerances in this type because the temperature coefficient, voltage coefficient, and stability may mean that it is only good for that tolerance at the time it was installed. The TCR of carbon film resistors is in the neighborhood of 100 to 200 ppm and is generally negative. Measuring and selecting can yield even tighter TCRs.

The frequency response of this type of resistor is among the best, far better than Wirewounds, and much better than carbon composition. The wire wound resistors are inductive at lower frequencies and values and somewhat capacitive at higher frequencies regardless of value. Also, wire wound resistors will have a resonant frequency. Carbon Composition Resistors will be predominately capacitive.


Metal Film resistors are the best compromise of all resistors. They are not as accurate have a higher temperature coefficient of resistance and are not as stable as Precision Wirewounds. They are more accurate, do not have a voltage coefficient, and have a lower temperature coefficient than Carbon Film. TCRs of 50 to 100 ppm can be achieved.

They have a very low noise level when properly manufactured. In fact, some of the screening processes measure the noise level to determine if there are problems in a particular batch of resistors.

Metal film resistors are manufactured by an evaporation/deposition process. That is the base metal is vaporized in a vacuum and deposited on a ceramic rod or wafer. Several attempts have been made to vaporize low TCR materials and deposit on these substrates, but to my knowledge, these attempts have not been successful. This is partially due to the different boiling points of the various base metals in these alloys (I use the word alloy not entirely accurately, for these materials are not true alloys but amalgamations — they do not bond to form a molecule as does a true alloy). The very low TCR resistive materials are heat treated to achieve the resistivity and low TCR. This is not compatible with an evaporation process.

The frequency characteristics of this type are excellent and better than Carbon Films. The one area where carbon films exceed metal films is the maximum values. Carbon films can achieve higher maximum values than any other group.


Foil resistors are similar in characteristics to metal films. Their main advantages are better stability than metal films and lower TCRs. They have excellent frequency response, low TCR, good stability, and are very accurate. They are manufactured by rolling the same wire materials as used in precision wire wound resistors to make thin strips of foil. This foil is then bonded to a ceramic substrate and etched to produce the value required. They can be trimmed further by abrasive processes, chemical machining, or heat treating to achieve the desired tolerance. Their main disadvantage is the maximum value is less than Metal Film Resistors.

The accuracy is about the same as metal film resistors, the TCR and stability approaches Precision Wirewounds but somewhat less because the rolling process and the packaging process produce stresses in the foil. The resistive materials used in Precision Wirewound Resistors is very sensitive to stresses which result in instability and higher TCRs. Any stresses on this material will result in a change in the resistance value and TCR, the greater the stress, the larger the change. This type can be used as a strain gauge, with strain being measured as a change in the resistance. When used as a strain gauge, the foil is bonded to a flexible substrate that can be mounted on a part where the stress is to be measured.


The Filament Resistors are similar to the Bathtub Boat Resistor except they are not packaged in a ceramic shell (boat). The individual resistive element with the leads already crimped is coated with an insulating material, generally a high-temperature varnish. These are used in applications where tolerance, TCR, and stability are not important but the cost is the governing consideration. The cost of this type is slightly higher that the carbon composition and the electrical characteristics are better.


Power film resistors are similar in manufacture to their respective metal film or carbon film resistors. They are manufactured and rated as power resistors, with the power rating being the most important characteristic. Power Film Resistors are available in higher maximum values than the Power Wirewound Resistors and have a very good frequency response. They are generally used in applications requiring good frequency response and/or higher maximum values. Generally for power applications, the tolerance is wider, the temperature rating is changed so that under full load resistor will not exceed the maximum design temperature, and the physical sizes are larger, and in some cases, the core may be made from a higher heat conductive material and other means to help radiate heat.