802.11N most closely matches this description.
shunt resistances are used to increase the range of ammetes and moreover it is praticularly then we have to low value shunt resistance.
Depends on the antenna, frequency, the reader power, and the design. Passive RFID's have a range from a few mm's to a few meters. In general, low frequency = near field rf = short range, higher frequency = far field rf = longer range. EPC HF near field tags have short ranges of less than 1 meter. EPC UHF tags are typically 1-2 meters reliable read. Far field range is very complex and it is possible to have multipath reflection arrangements where 10 meters may work... sometimes. With illegally high power transmitters, and large antennas, far field tags can be reliably read to tens of meters or more for non-commercial designs. Semi-passive RFID's can be read over hundreds of meters. Active RFID's are limited only by their transmit power and antenna design.
Because it is not necessary, and providing that bandwidth would increase cost and complexity. While the full range of 20Hz-20KHz is required for proper rendering of music, telephony, by standard, only requires a 3.5KHz bandwidth. You can hear and understand the spoken voice with only this range. You do not need the extended musical range.
With today's auto-ranging meters, you might well ask why. Today meters do that for you, and you might see it happening on some of them. In older meters, analog types in particular, you had to start with a higher range to be sure you didn't peg the meter measuring say, 220 volts when on the 10 volt scale. Lots of meters where toasted this way, their needles bent, or fuses blown by overcurrent. On higher ranges, the meter would deflect slightly, indicating there was voltage there, but not enough to get a accurate reading. So you scale down until hopefully you get a reading somewhere in mid scale, where the most accurate reading can be made. So the use was to protect the meter from damage, and provide the most accurate reading possible from an analog meter.
There is no defined range of values in C. The built-in types all have ranges that are defined in <stdint.h>, <limits.h> and <float.h>. These ranges are implementation-defined, they are not defined by the language or by the standard. The standard only defines minimum guarantees such that a char is always at least 8 bits long (CHAR_BIT) and that an int is at least as long as a short which is at least as long as a char.
The range of a standard IEEE WiFi repeater is around 35 meters indoors. However, this depends on a variety of factors, and the newer standards increase this to around 70 meters indoors.
I get my neighboors 802.11b wi-fi as one-bar signal strength, 25 feet across my backyard. So the range is prolly about 25-35 feet. (We have huge oaks Trees in the way that block signals)
The average price range for indoor bleachers is $500. Of course, that will depend on the brands and materials.
The Gander Mountain in Lake Mary off of I-4 has a small, but usuable indoor range.
In the Deathwatch RPG the range of a standard bloter is 30 meters.
50 meters. The maximum range is about 960 meters, but the maximum EFFECTIVE range is 50 meters.
FM 23-35 lists the maximum range of the M-9 as 1800 meters- the maximum effective range is 50 meters.
Elevation range is 10 meters!
That maximum range is nearly 2200 meters- HOWEVER, you may have meant the maximum EFFECTIVE range- which is 50 meters.
3600 meters - max range 550 meters - point target 800 meters - area target
Maximum range of a .40 cal pistol is about 960 meters. ACCURATE range is about 50 meters.
Could range from 14 to 20 years of age!