How telephone works
A telephone uses an electric current to convey sound information 
from your home to that of a friend. When the two of you are talking 
on the telephone, the telephone company is sending a steady 
electric current through your telephones. The two telephones, 
yours and that of your friend, are sharing this steady current. 
But as you talk into your telephone's microphone, the current 
that your telephone draws from the telephone company fluctuates 
up and down. These fluctuations are directly related to the air 
pressure fluctuations that are the sound of your voice at the microphone. 
Because the telephones are sharing the total current, any change 
in the current through your telephone causes a change in the current 
through your friend's telephone. Thus as you talk, the current through 
your friend's telephone fluctuates. A speaker in that telephone responds 
to these current fluctuations by compressing and rarefying the air. The 
resulting air pressure fluctuations reproduces the sound of your voice. 
Although the nature of telephones and the circuits connecting them have 
changed radically in the past few decades, the telephone system still 
functions in a manner that at least simulates this behavior. 
The current which powers your telephone is generated from the 48V 
battery in the central office. The 48V voltage is sent to the telephone 
line through some resistors and indictors (typically there is 2000 to 
4000 ohms in series with the 48V power source). The old ordinary 
offices had about 400 ohm line relay coils in series with the line. 
Here is a simplified picture of typical traditional telephone 
line interface: to 
Telephone central                              Telephone equipment

Ground -----+                               
            |                          Hookswitch  /
          COIL 5H                             +--o/ o-------+
            |                                 |             )|| ___
          Resistor 200 ohm                    |         ____)||(   |
      2uF   |                            TIP  |        |    )||( Speaker
    --||----+--o---------------------------o--+       Mic   )||(___|
Audio               Line wire                          |    )||
    --||----+--o---------------------------o-----------+----+
      2uF   |                            RING      
          Resistor 200 ohm                          
            |
          COIL 5H
            |  
-48V DC ----+
In some old switches there rere no separate reistors after the relay 
couils. Just a relay with 2x500 ohm coils was uased for both current
limiting and the coils between the line wires and the power source. 
When your telephone is in on-hook state the "TIP" is at about 0v, 
while "RING" is about -48v with respect to earth ground. When you 
go off hook, and current is drawn, TIP goes negative and RING goes 
positive (I mean less negative). A typical off hook condition is 
TIP at about -20v and ring at about -28v. This means that there is 
about 8V voltage between the wires going to telephone in normal 
operation condition. The DC-resistance of typical telephone equipment 
is in 200-300 ohm range and current flowing through the telephone is in 20-50 mA range. 
Why 48V voltage is used in telephone systems ?
The -48V voltage was selected because it was enough to get through 
kilometers of thin telephone wire and still low enough to be safe 
(electrical safety regulations in many countries consider DC voltages 
lower than 50V to be safe low voltage circuits). 48V voltage is also 
easy to generate from normal lead acid batteries (4 x 12V car battery 
in series). Batteries are needed in telephone central to make sure 
that it operates also when mains voltage is cut and they also give 
very stable output voltage which is needed for reliable operation 
of all the circuit in the central office. Typically the CO actually 
runs off of the battery chargers with the batteries in parallel getting 
a floating charge. 
The line feeding voltage was selected to be negative to make the 
electrochemical reactions on the wet telephone wiring to be less harmful. 
When the wires are at negative potential compared to the ground the metal 
ions go form the ground to the wire instead of the situation where 
positive voltage would cause metal from the wire to leave which 
causes quick corrosion. 
Some countries use other voltages in typically 36V to 60V range. 
PBXes may use as low as 24 Volts and can possibly use positive 
feeding voltage instead of the negative one used in normal telephone network. 
Positive voltage is more commonly used in many electronics circuits, 
so it is easier to generate and electrolysis in telecommunications wiring 
is not a problem in typical environment inside office buildings. 
Some older offices employ battery reversal (swap DC feed to tip 
and ring) to signal off-hook at the remote end. 
What is sealing current ?
The current sent to telephone line as an another advantage besides 
that it supplies the operating power for your telephone. Telephone 
practice uses (or did use) twisted splices. These splices did not 
always make good connections. Placing a small DC bias on a long 
transmission pair is often done by telecommuncation carriers to reduce 
poor connections, and noisy lines. The DC bias is often refered to as 
a "sealing current". So putting DC current through the cable sealed 
the connection and so improved the transmission. 
Why full duplex operation in single wire pair ?
Full-Duplex is a term used to describe a communications channel which 
is capable of both receiving and sending information simultaneously. 
Telephone sets (ordinary analog ones) have only 2 wires, which carry 
both speaker and microphone signals. The signal path between two 
telephones, involving a call other than a local one, requires 
amplification using a 4-wire circuit. The cost and cabling required 
ruled out the idea of running a 4-wire circuit out to the subscribers' 
premises from the local exchange and an alternative solution had to be 
found. Hence, the 4-wire trunk circuits were converted to 2-wire local 
cabling, using a device called a "hybrid". 
This function can send and receive audio signals at the same time is 
accomplished by designing the system so that there is a well balanced 
circuit in both ends of the wire which are capable or separating incoming 
audio from outgoing signal. This function is done by telephone hybrid 
circuit contained in the network interface of the telephone. 
What is the bandwidth of the telephone line ?
A POTS line (in the US and Europe) has a bandwidth of 3kHz. A normal 
POTS line can transfer the frequencies between 400 Hz and 3.4 Khz. 
The frequency response is limited by the telephone transmission system 
(the actual wire from central office to your wall can usually do much more). 
Nowadays POTS is sharply bandlimited due to the fact that the line 
almost always is digitally sampled at 8kHz at some point in the circuit. 
The absolute, theoretical limit (with perfect filters) is therefore 
4kHz - but this isn't reality, 3.4 kHz maximum frequency is. 
The bass frequency response is limted because of the limitations in 
telephone system components: transfromers and capacitors can be 
smaller if they don't have to deal with lowest frequencies. Other 
reason to drop out the lowest frequencies is to keep the possibly 
strong mains frequency (50 or 60 Hz and it's harmonics) hummign away 
from the audio signal you will hear. 

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