ZARLINK MT88E46AS

MT88E46
Bellcore Compliant Calling Number
Identification Circuit
Advance Information
Features
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Compatible with Bellcore GR-30-CORE,
SR-TSV-002476; TIA/EIA-716 and TIA/EIA-777
Pin compatible with MT88E45
Differential input amplifiers with adjustable
gains for Tip/Ring and 4-wire side connections
TIA (Telecommunications Industry Association)
MEI (Multiple Extension Interworking)
compatible architecture: CAS (CPE Alerting
Signal) detection is selectable between Tip/
Ring and 4-wire side
4-wire side CAS detection is Bellcore talkoff
and talkdown compliant when near end speech
is attenuated 8dB or better, and is close to
talkoff compliant even without near end speech
attenuation
Tip/Ring side CAS detection typically meets
talkdown condition 1 (the average case)
1200 baud Bell 202 and CCITT V.23 FSK
demodulation
Selectable 3-wire FSK data interface (serial bit
stream or 1 byte buffer) with facility to monitor
stop bit for framing error check
FSK carrier detect status output
3 to 5V ± 10% supply voltage
Uses 3.579545MHz crystal
Low power CMOS with power down mode
MT88E46AS
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IN1-
-
Description
The MT88E46 is a CMOS integrated circuit suitable
for receiving the FSK and CAS signals in North
American (Bellcore) CIDCW, CWD and CID (Calling
Identity Delivery) services. It provides an optimal
solution for the CIDCW (also known as Type 2) and
CWD (Type 2.5) telephone set applications by
providing separate input op-amps for Tip/Ring and 4wire side (receive pair of the telephone hybrid or
speech IC) connections. The Tip/Ring connection is
compatible with TIA’s MEI scheme and can be used
for FSK demodulation and ‘on hook mode’ CAS
detection. The 4-wire side connection is for ‘off hook
mode’ CAS detection. The CAS detection modes - on
hook and off hook - use different algorithms which
are optimized for the CPE states. In ‘off hook mode’
the CAS detector is Bellcore compliant when near
end speech is attenuated 8dB or better. ‘On hook
mode’ is optimized for talkdown only and typically
meets talkdown condition 1 (the average case)
without speech attenuation at Tip/Ring such as in the
on hook state MEI CPE.
MODE
FSK
Bandpass
GS1en
PWDN
IN2+
+
IN2-
-
Anti-Alias
Filter
PWDN
MODE
GS1en
FSKen CASen
PWDN
Control Bit
Decode
Oscillator
OSC2
DATA
DCLK
Data Timing
Recovery
Carrier
Detector
PWDN
Bias
Generator
OSC1
FSK
Demod
FSKen
CASen
GS2
VREF
CIDCW and CWD telephone adjunct boxes
Computer Telephony Integrated (CTI) systems
GS1en
IN1+
20 Pin SOIC
-40 to +85 °C
Bellcore compliant CIDCW (Calling Identity
Delivery on Call Waiting) and CWD (Call
Waiting Deluxe) telephones
GS1
March 2000
Ordering Information
Applications
•
ISSUE 1
2130Hz
Bandpass
2750Hz
Bandpass
CD
DR
Tone
Detection
Algorithm
DET
Mux
•
DS5350
DR/DET
Vdd
CASen
Vss
On/Off Hook mode
CB0 CB1 CB2
Patent pending
Figure 1 - Functional Block Diagram
1
MT88E46
Advance Information
VREF
1
20
IN2+
IN1+
2
19
IN2-
IN1-
3
18
GS2
GS1
4
17
CB2
Vss
5
16
CB1
OSC1
6
15
Vdd
OSC2
7
14
CD
CB0
8
13
NC
DCLK
9
12
IC
DATA
10
11
DR/DET
MT88E46
Figure 2 - Pin Connections
Pin Description
Pin #
Name
Description
1
VREF
Voltage Reference (Output). Nominally Vdd/2. It is used to bias the GS1 (Tip/Ring
connection) and GS2 (telephone hybrid or speech IC receive pair connection) input op-amps.
2
IN1+
GS1 Op-Amp Non-inverting Input. The op-amp is for connecting the MT88E46 to Tip/Ring.
3
IN1-
GS1 Op-Amp Inverting Input. The op-amp is for connecting the MT88E46 to Tip/Ring.
GS1
Gain Select 1 (Output). This is the output of the GS1 op-amp. The op-amp should be used to
connect the MT88E46 to Tip and Ring. The Tip/Ring signal can be amplified or attenuated at
GS1 via selection of the feedback resistor between GS1 and IN1-.
4
FSK demodulation or ‘on hook mode’ CAS detection of the GS1 signal can be selected via the
CB1 and CB2 pins. See Tables 1 and 2.
5
Vss
Power Supply Ground.
6
OSC1
Oscillator Input. Crystal connection. This pin can also be driven directly from an external
clock source.
7
OSC2
Oscillator Output. Crystal connection. When OSC1 is driven by an external clock, this pin
should be left open circuit.
Control Bit 0 (CMOS Logic Input). This pin is used primarily to select the 3-wire FSK data
interface mode. When it is low, interface mode 0 is selected where the FSK bit stream is output
directly at the DATA pin. When it is high, interface mode 1 is selected where the FSK byte is
stored in a 1 byte buffer which can be read serially by the application’s microcontroller.
8
CB0
The FSK interface is consisted of the DATA, DCLK and DR/DET pins. See the 3 pin
descriptions to understand how CB0 affects the FSK interface.
This pin is also used with CB1 and CB2 to put the MT88E46 into a power down state drawing
virtually no power supply current. See Tables 1 and 2.
9
DCLK
3-Wire FSK Interface Data Clock (Schmitt Logic Input/CMOS Logic Output). In interface
mode 0 (when the CB0 pin is logic low) this is a CMOS output whose rising edge denotes the
nominal mid-point of a bit in the FSK data byte.
In interface mode 1 (when the CB0 pin is logic high) this is a Schmitt trigger input used to shift
the FSK data byte out of an on chip buffer to the DATA pin.
2
Advance Information
MT88E46
Pin Description
Pin #
Name
Description
3-Wire FSK Interface Data (CMOS Logic Output). Mark frequency corresponds to logical 1.
Space frequency corresponds to logical 0.
In interface mode 0 (when the CB0 pin is logic low) the FSK serial bit stream is output to DATA
directly.
10
DATA
In interface mode 1 (when the CB0 pin is logic high) the start bit is stripped off, the data byte
and the trailing stop bit are stored in a 9 bit buffer. At the end of each word indicated by the DR
signal at the DR/DET pin, the microcontroller should shift the byte out to DATA by applying 8
read pulses to the DCLK pin. A 9th DCLK pulse will shift out the trailing stop bit for framing
error checking.
3-Wire FSK Interface Data Ready/CAS Detect (CMOS Logic Output). Active low.
This is a dual purpose pin which indicates the end of an FSK word or the end of CAS.
11
Data Ready: When FSK demodulation is enabled this pin denotes the end of a word. In both
FSK interface modes 0 and 1, it is normally high and goes low for half a bit time at the end of a
DR/DET word. In mode 1 if DCLK starts while DR is low, the first rising edge of the DCLK input will
return DR to high. This feature allows an interrupt requested by a low going DR to be cleared
upon reading the first DATA bit.
CAS Detect: When CAS detection is enabled, this pin goes low after the end of CAS for 416µs
(nominal) to indicate that CAS has been detected.
12
IC
Internal Connection. Must be left open circuit.
13
NC
No Connection. This pin is not bonded to the die and is unaffected by external connections.
14
CD
Carrier Detect (CMOS Logic Output). Active low.
A logic low indicates that an FSK signal is present. A 10ms time hysteresis has been provided
to allow for momentary signal discontinuity. The demodulated FSK data is ignored until carrier
detect has been activated.
15
Vdd
Positive Power Supply. A decoupling capacitor should be connected directly across the Vdd
and Vss pins.
16
CB1
Control Bit 1 (CMOS Logic Input). Together with CB2 this pin enables FSK demodulation or
CAS detection. See Tables 1 and 2.
17
CB2
Control Bit 2 (CMOS Logic Input). Together with CB1 this pin enables FSK demodulation or
CAS detection. See Tables 1 and 2.
Gain Select 2 (Output). This is the output of the GS2 op-amp. The op-amp should be used to
connect the MT88E46 to the receive pair of the telephone hybrid or speech IC. The signal can
be amplified or attenuated at GS2 via selection of the feedback resistor between GS2 and IN2.
18
GS2
When the application is a telephone adjunct box where there is no hybrid or speech IC, if the
GS2 gain with respect to Tip/Ring is to be set to the same as that of GS1, the GS2 op-amp can
be connected as a voltage follower to the GS1 op-amp output (see Figure 5).
The GS2 signal is used for ‘off hook mode’ CAS detection only as selected via the CB1 and
CB2 pins. See Tables 1 and 2.
19
IN2-
GS2 Op-Amp Inverting Input. The op-amp is for connecting the MT88E46 to the receive pair
of the telephone hybrid or speech IC.
20
IN2+
GS2 Op-Amp Non-Inverting Input. The op-amp is for connecting the MT88E46 to the receive
pair of the telephone hybrid or speech IC.
3
MT88E46
Advance Information
Control Bit (CB0/1/2) Functionality
FSK
Input
CB0 CB1 CB2 Interface
Op-Amp
0/1
0/1
0/1
1
1
0
1
0
1
Set by CB0
Set by CB0
Set by CB0
Function
GS1
FSK Demodulation. DR/DET pin is the DR signal.
GS2
‘Off hook mode’ CAS Detection. DR/DET pin is the DET signal.
The off hook mode algorithm is Bellcore talkoff and talkdown compliant
when near end speech level is attenuated 8dB or better. It should be used
for the off hook state CPE.
GS1
‘On hook mode’ CAS Detection. DR/DET pin is the DET signal.
When the line is in use, a TIA Multiple Extension Interworking (MEI)
compatible Type 2 CPE must be able to detect CAS even though the CPE
itself is on hook. Since in most telephone designs the hybrid or speech IC
is not operational when the CPE itself is on hook, this mode provides Tip
Ring CAS detection for the on hook state MEI CPE.
The on hook mode algorithm is optimized for talkdown only and typically
meets talkdown condition 1 (the average case) without near end speech
attenuation. It must not be used when the CPE itself is off hook. See ‘On
Hook Mode CAS Detection’ section in ‘Functional Description’.
1
0
0
Mode 1
-
0
0
0
Mode 0
-
Power Down. DR/DET pin is logic high.
The MT88E46 is disabled and draws virtually no power supply current.
Note that the DCLK pin becomes an input pin because FSK interface
mode 1 is selected by CB0=1.
Reserved for factory testing.
Table 1. CB0/1/2 Function Table
The number of control bits (CB) required to interface the MT88E46 to the microcontroller depends on the
functionality of the application.
Functionality Group
Controls
Description
FSK,
Off Hook mode CAS
(Non MEI compatible)
CB2
CB0 is connected to Vdd or Vss to select the FSK interface mode.
CB1 connected to Vdd.
The microcontroller uses CB2 to select between the 2 functions.
FSK,
Off Hook mode CAS,
On Hook mode CAS
CB1
CB2
CB0 is connected to Vdd or Vss to select the FSK interface mode.
The microcontroller uses CB1 and CB2 to select between the 3
functions.
FSK (Interface mode 1),
Off Hook mode CAS,
On Hook mode CAS,
Power Down
CB1
CB2
CB0 is connected to Vdd to select FSK interface mode 1.
The microcontroller uses CB1 and CB2 to select between the 4
functions.
FSK (Interface mode 0),
Off Hook mode CAS,
On Hook mode CAS,
Power Down
CB0
CB1
CB2
All 3 pins are required.
Table 2. Control Bit Functionality Groups
4
Advance Information
Functional Overview
In the Calling Identity Delivery on Call Waiting
(CIDCW) and Call Waiting Deluxe (CWD) services
offered by North American telephone operating
companies, a dual tone known as CAS (CPE Alerting
Signal) is sent from the central office to notify the
near end CPE, which is already engaged in an
established call, that the central office wishes to
deliver calling identity information of a waited call.
The signalling protocol is specified in Bellcore GR30-CORE, the CPE (Customer Premises Equipment)
requirements in SR-TSV-002476.
In the GR-30-CORE off hook protocol, the central
office mutes the far end connection (the other end of
the established call) just before CAS is transmitted.
When the near end CPE detects the CAS, it mutes
the handset and checks whether there is any parallel
off hook CPE. If there is no parallel off hook CPE, it
acknowledges CAS reception by sending ACK,
which is a predefined DTMF digit, back to the central
office. When the central office receives ACK, it
transmits the calling party information in 1200 baud
Bell 202 format FSK to the near end CPE which then
typically displays the information to the user.
When CAS is transmitted from the central office,
even though the far end has been muted the near
end user (the end which is to receive the caller ID
information) may be speaking. Therefore, the CAS
must be detected in the presence of near end
speech, noise or music. Failure to detect the CAS
and reply with ACK within a defined interval is known
as ‘talkdown’. Talkdown is undesirable because the
central office will not deliver the calling information,
hence the quality of the CIDCW or CWD service will
be degraded.
Since CAS can be transmitted anytime during an
established call, the CAS detector is therefore
subjected to speech, noise or music - which can
imitate CAS - from both the near end and the far end
throughout the call. False detection followed by ACK
is known as ‘talkoff’. Talkoff is undesirable because it
annoys the far end user by the near end CPE’s
sending ACK and because the near end CPE is
muted in anticipation of the FSK signal.
Bellcore has specified talkdown and talkoff immunity
performance requirements in SR-TSV-002476. If the
CPE is a telephone, one way to achieve good CAS
speech immunity is to put CAS detection on the
receive pair of the telephone hybrid or speech IC
instead of on Tip and Ring. Compared to a Tip/Ring
connection, talkdown immunity improves because
the near end speech is attenuated on the hybrid /
MT88E46
speech IC receive pair while the CAS level is the
same as on Tip/Ring. Talkoff immunity is also better
because the near end speech is attenuated.
In the GR-30-CORE issue 1 off hook protocol, the
near end CPE must not ACK if there is a parallel off
hook CPE. Otherwise the ACK will not be detected
reliably at the central office. This restriction is
modified by a protocol known as MEI (Multiple
Extension Interworking) developed by the TIA
(Telecommunications Industry Association) in
conjunction with Bellcore. MEI allows a CPE to ACK
if all off hook CPEs are MEI compatible. MEI is
described in the TIA/EIA-777 standard.
MEI introduces the concept of the ACK-Sender and
the Backup ACK-Sender.
• On a per call basis, the ACK-Sender is the first
CPE to go off hook for the call. It retains its
status even if it returned on hook while the line
remains in use. The ACK-Sender must give up
its status if a Type 3 (Analog Display Services
Interface) CPE asserts its ACK-Sender status.
• The Backup ACK-Sender is the CPE to last
respond to CAS with an ACK and successfully
received FSK data. It retains its status from call
to call but must give up its Backup ACK-Sender
status when another CPE successfully
completes the CAS-ACK-FSK sequence.
When CAS is sent from the central office, all MEI
compatible off hook CPEs detect CAS and go back
on hook. After the ACK-Sender detected CAS, it
monitors the line voltage. When the line voltage has
returned to the HIGH state (the voltage when the line
is not terminated by any CPE), it goes off hook and
sends the ACK. If there is no ACK-Sender because
the first CPE to go off hook is not MEI compatible,
the Backup ACK-Sender takes over and sends the
ACK. Note that both the ACK-Sender and the
Backup ACK-Sender can be on hook or off hook.
Because it may be the ACK-Sender or Backup ACKSender, an MEI compatible on hook state CPE must
be able to detect CAS when the line is in use.
Additionally, the TIA/EIA-777 standard requires an
MEI on hook state CPE to detect CAS during a call
so that it can listen in on the FSK to keep its call log
consistent with the off hook CPEs. However, a CAS
detector connected only to the hybrid / speech IC
cannot detect CAS when the CPE itself is on hook
because either the hybrid / speech IC is not
operational or the signal level is severely attenuated.
Therefore an MEI compatible CPE must be able to
detect CAS from Tip/Ring when the CPE is on hook,
and be able to detect CAS from the hybrid / speech
IC when the CPE is off hook.
5
MT88E46
Advance Information
The MT88E46 offers an optimal solution which
combines Bellcore compliant speech immunity and
MEI compatibility. Two input op-amps allow the
MT88E46 to be connected to both Tip/Ring and to
the receive pair of the telephone hybrid or speech IC
(the 4-wire side). Each connection can be differential
or single ended. FSK demodulation is available only
at the Tip/Ring connection. The CAS detector
operates in ‘on hook mode’ and ‘off hook mode’ using
different algorithms optimized for the CPE states. On
hook mode is available only at the Tip/Ring
connection, while off hook mode is available only at
the 4-wire side connection.
compatible with Bellcore and TIA standards. The
demodulated FSK data is either output directly (bit
stream mode) or stored in a one byte buffer (buffer
mode) which can be shifted out. In the buffer mode,
the stop bit immediately following a byte is also
stored and can be shifted out after the data byte.
This facility allows for framing error checking as
required in TIA/EIA-777 for the Type 2 CPE. In the bit
stream mode, two timing signals are provided. One
indicates the bit sampling instants of the data byte,
the other the end of the byte. A carrier detector
indicates the presence of signal and shuts off the
data stream when there is no signal.
The ‘off hook mode’ is Bellcore compliant when the
near end speech is attenuated 8dB or better. It
should be used when the CPE is off hook. The ‘on
hook mode’ is optimized for talkdown only and
typically meets talkdown condition 1 (the average
case) without near end speech attenuation to provide
Tip/Ring CAS detection for the on hook state MEI
CPE. It should be used when the CPE itself is on
hook but the line is in use.
The entire chip can be put into a power down mode
consuming virtually no power supply current. The
input op-amps, FSK demodulator, CAS detector and
the oscillator are all shut off. Furthermore, partial
power down has been incorporated to minimize the
operating current: when FSK is selected, the CAS
detector is powered down; when CAS is selected,
the FSK demodulator is powered down. The two
input op-amps are not affected by partial power down
and will remain operational regardless of whether
FSK or CAS is selected.
The FSK demodulator is suitable for both Bell 202
and CCITT V.23 formats transparently, and is
SR-TSV-002476
Requirement
Test Result for
0dB Near End
Speech
Attenuation using
Pre-emphasized
Speech only
Test Result for 0dB Near
End Speech Attenuation
using Pre-emphasized
Speech for Near End,
Normal Speech for Far
End
Test Result for 6dB Near
End Speech Attenuation
using Pre-emphasized
Speech only
Vdd = 5V ± 10%, GS2 gain = 0dB
Condition 1
1 in ≥ 45 hours
1 in 48.0 hours
1 in 96.0 hours
1 in 96.0 hours
Condition 2
1 in ≥ 10 hours
1 in 8.6 hours
1 in 10.1 hours
1 in 16.5 hours
Condition 3
1 in ≥ 35 hours
1 in 37.4 hours
1 in 43.0 hours
1 in 113.1 hours
Vdd = 3V ± 10%, GS2 gain = -4dB
Condition 1
1 in ≥ 45 hours
1 in 32.0 hours
TBD
1 in 192.0 hours
Condition 2
1 in ≥ 10 hours
1 in 10.6 hours
TBD
1 in 19.9 hours
Condition 3
1 in ≥ 35 hours
1 in 39.8 hours
TBD
1 in 123.0 hours
Table 3. Typical Off Hook Mode Talkoff Immunity Performance
SR-TSV-002476
Requirement
Test Result for 0dB Near End
Speech Attenuation
Test Result for 8dB Near End
Speech Attenuation
Vdd = 5V ± 10% (GS2 gain = 0dB) and 3V ± 10% (GS2 gain = -4dB)
Condition 1
≥ 99.5%
99.2%
99.9%
Condition 2
≥ 93.0%
79.6%
93.5%
Condition 3
≥ 99.5%
97.6%
99.7%
Table 4. Typical Off Hook Mode Talkdown Immunity Performance
6
MT88E46
Advance Information
Preliminary Off Hook Mode CAS
Detector Speech Immunity Performance
Since there is some randomness in speech immunity
testing, and because the telephone hybrid / speech
IC design will affect the result, the preliminary test
results in Tables 3 and 4 are provided to illustrate
typical performances only.
In Table 3 (talkoff results) column 3, the result was
obtained using pre-emphasized speech as both the
near end and far end speech sources. It is
pessimistic, as recognized in SR-TSV-002476,
because in reality the pre-emphasis originally
imparted on the far end speech by the far end CPE’s
microphone would have been equalized by the
subscriber loop, so that at the near end CPE Tip/
Ring terminals the far end speech would have no
pre-emphasis. Table 3 column 4 shows the result for
the same situation as column 3 except that preemphasized speech was used only as the near end
speech source and normal speech was used as the
far end speech source, as allowed in SR-TSV002476.
In Table 3 column 5 and Table 4 column 4, the
MT88E46 performance with a telephone hybrid /
speech IC was simulated during testing by
attenuating the pre-emphasized near end speech
equally at all frequencies. The actual performance
will depend on the telephone hybrid / speech IC
design.
Functional Description
3 to 5V Operation
Tip and Ring. The GS2 op-amp (IN2+, IN2-, GS2
pins) is for connecting to the receive pair of the
telephone hybrid or speech IC in the telephone set
application.
Either FSK demodulation or ‘on hook mode’ CAS
detection can be selected for the GS1 signal. Only
‘off hook mode’ CAS detection is available for the
GS2 signal. ‘On hook mode’ CAS detection at the
GS1 op-amp is intended for the MEI on hook CPE
situation. ‘Off hook mode’ CAS detection at the GS2
op-amp is intended for the off hook CPE situation.
The feedback resistor connected between IN1- and
GS1 can be used to adjust the Tip/Ring path input
gain, and the feedback resistor between IN2- and
GS2 can be used to adjust the hybrid / speech IC
path input gain. When the GS1 op-amp is selected,
the GS2 signal is ignored. When the GS2 op-amp is
selected, the GS1 signal is ignored.
Either or both op-amps can be configured in the
single ended input configuration shown in Figure 3,
or in the differential input configuration shown in
Figure 4.
IN+
C
RIN
IN-
GS
RF
Passband Voltage Gain
AV = RF / RIN
Highpass Corner Frequency
f-3dB= 1/(2πRINC)
VREF
Figure 3 - Single Ended Input Configuration
The MT88E46 is designed to operate from a fixed
voltage power supply between 3 and 5V nominal. A
±10% variation from the nominal voltage is allowed.
Its FSK and CAS reject levels are proportional to
Vdd. When operated at Vdd equals 3V ± 10%, to
keep the FSK and CAS reject levels as at 5V ± 10%,
and for optimal speech immunity, the GS1 and GS2
op-amp gains should be reduced from those of 5V.
Gains for nominal Vdd’s between 3 and 5V can be
obtained by interpolation between the 3V and 5V
values shown in Figure 9.
Input Configuration
The MT88E46 provides an input arrangement
comprised of two op-amps and a bias source (VREF).
VREF is a low impedance voltage source which is
used to bias the op-amp inputs at Vdd/2. The GS1
op-amp (IN1+, IN1-, GS1 pins) is for connecting to
C1
IN+
R1
IN-
C2
R2
R4
R3
GS
R5
VREF
Differential Input Amplifier
C1 = C2
R2 = R1 (For unity gain R3= R1)
R4 = (R3R5) / (R3 + R5)
Highpass Corner Frequency
Passband Voltage Gain
f-3dB= 1/(2πR1C1)
(AVdiff) = R3/R1
Input Impedance
(ZINdiff) = 2
R12 + (1/ωC1)2
Figure 4 - Differential Input Configuration
7
MT88E46
Advance Information
In a telephone adjunct box application where there is
no hybrid or speech IC, if the GS2 gain with respect
to Tip/Ring is to be set to the same as that of GS1,
the GS2 op-amp can be connected as a voltage
follower to the GS1 op-amp output as shown in
Figure 5.
GS1
GS1 op-amp configured
as in Figure 3 or 4
IN2+
IN2-
GS2
Figure 5 - GS2 Op-Amp Connected as GS1
Voltage Follower
hybrid or speech IC. When near end speech is not
attenuated, such as from a parallel off hook CPE or
when the application is a telephone adjunct box,
talkoff is close to compliant while talkdown is close to
condition 1 (the average case). This mode is
intended for the off hook CPE situation and is
available at the GS2 (4-wire side) input op-amp only.
On Hook Mode CAS Detection
The ‘on hook mode’ is optimized for talkdown only. It
typically meets talkdown condition 1 without near
end speech attenuation. It is intended for the MEI on
hook CPE situation and must not be used when the
CPE itself is off hook. The input is the GS1(Tip/Ring)
op-amp because in most CPE designs, to detect
CAS when the CPE itself is on hook, the signal must
come from the Tip/Ring connection since either the
telephone hybrid / speech IC is not operational or the
4-wire side signal level is severely attenuated.
CAS Detection
When CAS detection is selected, the dual purpose
DR/DET pin is the DET output signal. DET goes low
momentarily (416 µsec nominal) after the end of
CAS to indicate that CAS has been detected, as
shown in Figure 13. The CAS detector operates in
‘off hook mode’ or ‘on hook mode’ as selected by the
CB1 and CB2 pins (see Table 1). ‘On hook mode’
and ‘off hook mode’ use different algorithms
optimized for the CPE states.
Normally DET goes low after the end of CAS.
However, because of interference from speech or
music, DET may go low before the end of CAS. The
on hook and off hook mode algorithms ensure that
DET will occur no earlier than tDET1 after the
beginning of CAS (see Figure 13).
Similarly, speech interference can cause DET to go
low later than tDET2 after the end of CAS (see Figure
13). In off hook mode, the detection algorithm
ensures that DET will occur no later than 35ms after
the end of CAS even with speech interference, as
required in TIA/EIA-777. In on hook mode, although
the detection algorithm does not limit the detection
delay from the end of CAS, talkdown typically meets
the SR-TSV-002476 talkdown condition 1 (the
average case) when only the detections which occur
from the beginning of CAS to 35ms after the end of
CAS are counted.
Off Hook Mode CAS Detection
The ‘off hook mode’ is Bellcore talkdown and talkoff
compliant when the near end speech is attenuated
8dB or better, such as provided by the telephone
8
In the MEI protocol, the ACK-Sender and Backup
ACK-Sender can be on hook or off hook. Therefore, if
the on hook state CPE is the ACK-Sender or the
Backup ACK-Sender, it must be able to detect CAS
when the line is in use. Additionally, an on hook state
MEI CPE must be able to detect CAS during a call so
that it can listen in on the FSK to keep its call log
consistent with the off hook CPEs, as required in
TIA/EIA-777.
The MT88E46 on hook mode algorithm has been
optimized for talkdown because of the way the MEI
protocol works. In MEI, the following events
(described in TIA/EIA-777) occur when CAS is
detected:
• Each off hook CPE shall proceed to the on hook
state not earlier than 25ms and no later than
60ms after the end of CAS as measured on Tip/
Ring. (The 25ms delay is necessary to prevent
the on hook transition from corrupting the CAS
for other CPEs that may not have completely
qualified the signal. The additional 35ms that
defines the 60ms upper limit allows for variation
in CAS detection delay.)
• After detecting a line HIGH state (the line
voltage when the line is not terminated by any
CPE), the ACK-Sender shall go off hook. The
ACK-Sender shall allow the line to remain in the
HIGH state for at least 5ms but not more than
8ms. If no line HIGH state is detected within
100ms after going on hook, all previously off
hook CPE shall return to the off hook state.
• Following a CAS the Backup ACK-Sender shall
monitor the line for a line HIGH state lasting a
minimum of 15ms. Once this condition has
been detected, the Backup ACK-Sender shall
Advance Information
•
•
immediately become the ACK-Sender, go off
hook no later than 20ms after the start of the
line HIGH state, complete the CAS-ACK
handshake, and remain as ACK-Sender for the
remainder of the call. This situation may
happen if the designated ACK-Sender is not
MEI compliant.
An MEI compliant CPE that is not the
designated ACK-Sender or the Backup ACKSender but which is off hook at the time of the
CAS, shall monitor the line for a line HIGH state
lasting a minimum of 30ms. Once this condition
has been detected, the CPE shall immediately
become the ACK-Sender, go off hook no later
than 35ms after the start of the line HIGH state,
complete the CAS-ACK handshake, and remain
as ACK-Sender for the duration of the call. This
situation can happen if the designated ACKSender and the Backup ACK-Sender are not
MEI compliant.
After going off hook the ACK-Sender shall
begin transmission of the ACK no earlier than
30ms and no later than 40ms after the leading
edge of the line HIGH voltage transition.
After the ACK-Sender or Backup ACK-Sender
detected CAS, it must monitor the line for the line
HIGH state, which can happen only if all off hook
CPEs also detected CAS. Hence if the ACK-Sender
or Backup ACK-Sender is an on hook CPE, even if it
falsely detected CAS, talkoff can occur only if all off
hook CPEs also falsely detected CAS. Thus in the
situation where the ACK-Sender or Backup ACKSender is an on hook CPE using the MT88E46 on
hook mode detection algorithm, talkoff protection is
provided by the off hook CPEs. The on hook mode
has been optimized to be more talkdown immune so
that in this situation the on hook CPE will be
successful in fulfilling its ACK-Sender or Backup
ACK-Sender responsibility.
FSK Demodulation
The FSK demodulator is compatible with Bellcore
SR-TSV-002476, TIA/EIA-716 and TIA/EIA-777
standards. It is capable of both Bell 202 and CCITT
V.23 formats transparently. FSK demodulation is
available at the GS1 input op-amp only.
FSK Data Interface
The MT88E46 provides a powerful dual mode 3-wire
interface so that the data bytes in the demodulated
FSK bit stream can be extracted without the need
either for an external UART or for the CPE’s
microcontroller to perform the function in software.
MT88E46
The interface is specifically designed for the 1200
baud rate and is consisted of 3 signals: DATA, DCLK
(Data Clock) and DR (Data Ready). DATA is an
output pin. DCLK is an input output pin. DR uses the
dual purpose output pin DR/DET. When FSK is
selected it is the DR signal.
Two FSK interface modes (modes 0 and 1) are
selectable via the CB0 pin. In mode 0, the FSK bit
stream is output directly. In mode 1, the data byte
and the trailing stop bit are stored in a 9 bit buffer. If
mode 1 is used, the CB0 pin can be connected to
Vdd. If mode 0 is used and full chip power down is
not required, the CB0 pin can be connected to Vss.
In Bellcore’s off hook protocol, a Type 2 CPE should
restore the voicepath within 50ms after the end of
the FSK signal. Due to noise, end of carrier detection
is not always reliable. The TIA/EIA-777 standard
requires the CPE to detect the end of FSK when any
one of the following occurs:
• absence of carrier signal or,
• more than five framing errors (trailing stop bit a
0 instead of a 1) have been detected in the FSK
message or,
• more than 150ms of continuous mark signal or
space signal has been detected.
FSK Data Interface Mode 0 - Bit Stream Mode
This mode is selected when the CB0 pin is low. In
this mode the FSK data is output directly to the DATA
pin. DCLK and DR are timing signal outputs (see
Figure 14).
For each received stop and start bit sequence, the
MT88E46 outputs a fixed frequency clock string of 8
pulses at the DCLK pin. Each DCLK rising edge
occurs in the middle of a DATA bit of the FSK byte.
DCLK is not generated for the start and stop bits.
Consequently, DCLK will clock only valid data into a
peripheral device such as a serial to parallel shift
register or into a microcontroller. The MT88E46 also
outputs an end of word pulse DR (Data Ready). DR
goes low for half a nominal bit time at the beginning
of the trailing stop bit. It can be used to interrupt a
microcontroller or cause a serial to parallel converter
to parallel load its data into the microcontroller. If a
shift register is not used, DCLK and DATA may
occupy 2 bits of a microcontroller’s input port. The
microcontroller polls the input port and saves the
DATA bit when DCLK changes from low to high.
When DR goes low, the word may then be
assembled from the last 8 saved bits.
9
MT88E46
Advance Information
Since the DR rising edge occurs in the middle of the
trailing stop bit, it can be used to read the stop bit to
check for framing error. Alternatively, at the DR
falling edge the microcontroller can set a timer for a
1/2400 second timeout and read the stop bit at DATA
when the timer times out.
DATA may also be connected to a personal
computer’s serial communication port after
conversion from CMOS to RS-232 voltage levels.
FSK Data Interface Mode 1 - Buffer Mode
This mode is selected when the CB0 pin is high. In
this mode the received byte is stored on chip. At the
end of a byte DR goes low to indicate that a new byte
has become available. The microcontroller applies
pulses at the DCLK input pin to read the register
contents serially out of the DATA pin (see Figure 15).
activated. CD is released when there is no activity at
the FSK bandpass filter output for 10ms.
When CD is inactive (high), the raw output of the
FSK demodulator is ignored by the internal data
timing recovery circuit. In FSK interface mode 0 the
DATA, DCLK and DR outputs are forced high. In
mode 1 the output shift register is not updated and
DR is high; if DCLK is clocked, DATA is undefined.
Note that signals such as speech, CAS and DTMF
tones also lie in the FSK frequency band and the
carrier detector may be activated by these signals.
They will be demodulated and presented as data. To
avoid the false data, the MT88E46 should be put into
CAS or power down mode when FSK is not
expected. Ringing, on the other hand, does not pose
a problem as it is ignored by the carrier detector.
Interrupt
Internal to the MT88E46, the start bit is stripped off,
the data bits and the trailing stop bit are sampled and
stored. Midway through the stop bit, the 8 data bits
and the stop bit are parallel loaded into a 9 bit shift
register and DR goes low. The register’s contents are
shifted out to the DATA pin on the supplied DCLK’s
rising edges in the order they were received. The last
bit must be shifted out and DCLK returned to low
before the next DR. DCLK must be low for tDDS
before DR goes low and remain low for tDDH after DR
has gone low (see Figure 15 and ‘AC Electrical
Characteristics - Mode 1 FSK Data Interface
Timing’).
The DR/DET output can be used to interrupt a
microcontroller. When the MT88E46 is the only
interrupt source, DR/DET can be connected directly
to the microcontroller’s interrupt input. Figure 7
shows the necessary connections when the
MT88E46 is one of many interrupt sources. The
diodes and resistors implement a wired-or so that the
microcontroller is interrupted (INT low active or
falling edge triggered) when one or more of INT1,
INT2 or DR/DET is low. The microcontroller can
determine which one of DR/DET, INT1 or INT2
caused the interrupt by reading them into an input
port.
If DCLK begins while DR is low, DR will return to high
upon the first DCLK rising edge. If DR interrupts a
microcontroller then this feature allows the interrupt
to be cleared by the first read pulse. Otherwise DR is
low for half a nominal bit time (1/2400 sec).
Power Down
Reading the stop bit allows the software to check for
framing errors. When framing error is not checked
the microcontroller only needs to send 8 DCLK
pulses to shift the data byte out.
FSK Carrier Detector
The carrier detector provides an indication of the
presence of a signal in the FSK frequency band. It
detects the presence of a signal of sufficient
amplitude at the output of the FSK bandpass filter.
The signal is qualified by a digital algorithm before
the CD output is set low to indicate carrier detection.
A 10ms hysteresis has been provided to allow for
momentary signal dropout once CD has been
10
The MT88E46 can be powered down to consume
virtually no power supply current via a state of the
CB0/1/2 pins. Momentary transition of CB0/1/2 into
the power down code will not activate power down. In
power down mode both input op-amps, VREF and the
oscillator are not operational; DCLK becomes an
input pin because to select the power down state
CB0 is 1 which selects FSK interface mode 1. If the
application uses FSK interface mode 0 and the
MT88E46 needs to be powered down, then during
power down the input state of the DCLK input must
be defined, for example, by a pull down resistor (R13
in Figure 8) so that the MT88E46 will draw minimal
power supply current. When the MT88E46 is
powered down DATA, DR/DET, CD are high.
To reduce the operating current a partial power down
feature has been incorporated. When FSK is
selected, the CAS detector is powered down. When
CAS is selected the FSK demodulator is powered
Advance Information
MT88E46
down. The two input op-amps are not affected and
both will remain operational.
Maximum Drive Level:
e.g. CTS MP036S
2mW
The partial power down feature can also be used to
reset the FSK or CAS circuits, such as upon system
power up. To reset the FSK demodulator, use CB1/2
to select CAS mode for about 10µs, DR will become
high. To reset the CAS detector, select FSK mode for
about 10µs, DET will become high.
Alternatively an external clock source can be used.
In which case the OSC1 pin should be driven directly
from a CMOS buffer and the OSC2 pin left open.
For 5V±10% applications any number of MT88E46’s
can be connected as shown in Figure 6 so that only
one crystal is required.
Oscillator
MT88E46
The MT88E46 requires a 3.579545MHz crystal to
generate its oscillator clock. To meet the CAS
detection frequency tolerance specifications the
crystal must have a 0.1% frequency tolerance. The
crystal specification is as follows:
OSC1
MT88E46
OSC2
OSC1
OSC2
MT88E46
OSC1
to the
next MT88E46
3.579545 MHz
Frequency:
Frequency Tolerance:
Resonance Mode:
Load Capacitance:
Maximum Series Resistance:
Interrupt Source 1
3.579545MHz
±0.1% (over
temperature range
of the application)
Parallel
18pF
150Ω
Vdd
R1
INT1
(Open Drain)
Interrupt Source 2
(For 5V±10% applications only)
Figure 6 - Common Crystal Connection
Vdd
D1
OSC2
Microcontroller
R2
R1 can be opened and
D1 shorted if the
microcontroller does not
read the INT1 pin.
INT2
(CMOS)
INT (input)
MT88E46
DR/DET
(CMOS)
Input Port Bit
Figure 7 - Application Circuit: Multiple Interrupt Sources
11
MT88E46
Advance Information
Tx+
TIP
TIP
RING
Telephone
Hybrid or
Speech IC
(Symbolic)
RING
Microphone
Tx-
Rx+
Speaker
Rx-
R5
C1
D1
R1
R6
R11
R3
R8 C3
VREF
D2
IN2+
IN1+
IN2MT88E46
D3
R10
IN1-
GS2
GS1
CB2
Vss
CB1
OSC1
Vdd
OSC2
CD
CB0
NC
R12
R9 C4
R7
R4
C2 R2
D4
± 10% power
supply
= To Microcontroller
Vss Xtal
= From Microcontroller
(FSK Interface Mode 1 selected)
R13 is required only if both FSK
interface mode 0 and power
down features are used.
C5
DCLK
IC
DATA
DR/DET
R13
C5 should be connected
directly across the Vdd
and Vss pins.
Unless stated otherwise, resistors are 1%, 0.1Watt; capacitors are 5%, 6.3V.
For 1000Vrms, 60Hz isolation from Tip to Earth and Ring to Earth:
R1,R2
430K, 0.5W, 5%, 475V minimum
C1,C2
2n2, 1332V minimum
(e.g. IRC type GS-3)
If the 1000Vrms is handled by other methods then this circuit has to meet the FCC Part 68 Type B Ringer requirements:
R1,R2
432K, 0.1W, 1%, 56V minimum
C1,C2
2n2, 212V minimum
Common to both sets of R1,R2 and C1,C2:
R3,R4
34K
R8, R9
464K
R13
100K, 20%. Required only if both FSK interface mode 0 and power down features are used.
C3,C4
2n2
C5
100n, 20%
D1-D4
Diodes. 1N4148 or equivalent
Xtal
3.579545MHz, 0.1% crystal
Vdd =
GS1 Gain
R5
R6
R7
5V±10%
0dB
53K6
60K4
464K
3V±10%
-4.0dB (preliminary)
34K0
38K3
294K
Vdd =
GS2 Gain
R10
R11
R12
5V±10%
0dB
53K6
60K4
464K
3V±10%
-4.0dB (preliminary)
34K0
38K3
294K
In a telephone adjunct box application where there is no hybrid or speech IC, if the GS2 gain with respect to Tip/Ring is to be set
to the same as GS1, the GS2 op-amp can be connected as a voltage follower to the GS1 output as shown in Figure 5.
Figure 8 - Application Circuit: MEI Compatible Type 2 Telephone
12
Advance Information
MT88E46
1.000
1.00
PRELIMINARY
0.95
Gain Ratio
0.90
0.85
0.80
0.75
0.70
0.65
0.63095
0.60
3.0
3.5
4.0
4.5
5.0
Nominal Vdd (Volts)
Figure 9 - GS1 and GS2 Gain Ratios as a Function of Nominal Vdd
Gain Setting Resistor Calculation for Nominal Vdd between 3 and 5V
•
•
•
•
For the desired nominal Vdd, use Figure 9 to calculate approximate Av.
For the GS1 op-amp, start with the 0dB gain setting resistor values of R50dB, R60dB and R70dB. In
Figure 8 they are 53K6, 60K4 and 464K respectively. Keep R1, R2, R3, R4, C1, C2 as in Figure 8 to
keep the input highpass filter corner frequency constant for all gain settings.
For the desired Av:
R7Av = R70dB x Av
Scaled for desired gain. Choose the closest standard 1%
resistor value as R7Av. Calculate Av_actual as R7Av/R70dB.
R5Av= R50dB x Av_actual
Scaled for good common mode range. Choose the closest
standard 1% resistor as R5Av.
Calculate R6Av so that R5Av = R6Av || R7Av. Choose the
1/R6Av= 1/R5Av-1/R7Av
closest standard 1% resistor as R6Av.
Repeat for R10, R11 and R12 for the GS2 op-amp.
Example:
•
•
•
•
For the 3V gain of -4.0dB, Av = 0.63095.
R7-4dB = 0.63095 x 464K = 292.76K. The closest standard 1% resistor is 294K.
Av_actual is 294K/464K = 0.63362 or -3.96dB.
R5-4dB = 0.63362 x 53K6 = 33.96K. The closest standard 1% resistor is 34K0.
1/R6-4dB = 1/34.0K - 1/294K = 1/38.45K. The closest standard 1% resistor is 38K3.
13
MT88E46
Advance Information
Absolute Maximum Ratings* - Voltages are with respect to Vss unless otherwise stated
Parameter
Sym
Min
Max
Units
1
Supply voltage with respect to Vss
Vdd
-0.3
6
V
2
Voltage on any pin other than supplies **
VPIN
Vss-0.3
Vdd+0.3
V
3
Current at any pin other than supplies
IPIN
-
10
mA
4
Storage Temperature
TST
-65
150
oC
* Exceeding these values may cause permanent damage. Functional operation under these conditions is not implied.
** Under normal operating conditions voltage on any pin except supplies can be minimum Vss-1V to maximum Vdd+1V for an input
current limited to less than 200µA.
Recommended Operating Conditions - Voltages are with respect to ground (Vss) unless otherwise stated
Characteristics
Sym
Min
Typ‡
Max
Units
1
Power Supplies
Vdd
2.7
-
5.5
V
2
Clock Frequency
fOSC
-
3.579545
-
MHz
3
Tolerance on Clock Frequency
∆fOSC
-0.1
-
+0.1
%
4
Operating Temperature
TOP
-40
-
85
oC
‡Typical figures are at 25˚C and are for design aid only: not guaranteed and not subject to production testing.
DC Electrical Characteristics†
Characteristics
1
2
S
U
P
P
L
Y
3
4
DCLK
5
6
7
14
CB0
CB1
CB2
DCLK
DATA
DR/DET
CD
Power Down Mode
Supply Current
Sym
IDDQ
Operating Supply
Current
Vdd = 5V ±10%
Vdd = 3V ±10%
IDD
Power Consumption
Min
-
Typ‡
0.1
Max
15
Units
Test Conditions
µA
All inputs are at Vdd/
Vss except for
oscillator pins,
outputs unloaded.
CB0/1/2 = 100
-
4.3
2.7
8
4.5
mA
mA
PO
-
-
44
mW
Schmitt Input High
Threshold
VT+
0.48*Vdd
-
0.68*Vdd
V
Schmitt Input Low
Threshold
VT-
0.28*Vdd
-
0.48*Vdd
V
Schmitt Hysteresis
VHYS
0.2
-
-
V
CMOS Input High
Voltage
VIH
0.7*Vdd
-
Vdd
V
CMOS Input Low
Voltage
VIL
Vss
-
0.3*Vdd
V
Output High Source
Current
IOH
0.8
-
-
mA
All inputs are at Vdd/
Vss except for
oscillator pins. No
analog input, outputs
unloaded.
VOH=0.9*Vdd
MT88E46
Advance Information
DC Electrical Characteristics† (continued)
Sym
Min
Typ‡
Max
Units
IOL
2
-
-
mA
VOL=0.1*Vdd
IIN1
-
-
1
µA
VIN=Vdd to Vss
IIN2
-
-
10
µA
VIN=Vdd to Vss
Output Voltage
VREF
0.5Vdd
-0.1
-
0.5Vdd
+0.1
V
No Load
Output Resistance
RREF
-
-
2
kΩ
Characteristics
8
9
10
11
DCLK
DATA
DR/DET
CD
IN1+
IN1IN2+
IN2DCLK
CB0
CB1
CB2
VREF
Output Low Sink
Current
Test Conditions
Input Current
†DC Electrical Characteristics are over recommended operating conditions, unless otherwise stated.
‡Typical figures are at 25˚C and are for design aid only: not guaranteed and not subject to production testing.
AC Electrical Characteristics† - CAS Detection
Characteristics
Sym
Min
Typ‡
Max
Unit
Notes*
1
Upper Tone Frequency
fH
2736.2
2750
2763.8
Hz
1
2
Lower Tone Frequency
fL
2119.3
2130
2140.7
Hz
1
3
Accept Signal Level (per tone)
-32
-34.22
-
-14
-16.22
dBm
dBV
1, 2, 3, 4, 5
4
‘Off Hook mode’ Reject Signal Level
(per tone)
-
-
-45
-47.22
dBm
dBV
1, 2, 4, 6
5
Twist: 20 log (V2130Hz/V2750Hz)
-6
-
+6
dB
6
‘Off Hook mode’ Accept CAS Duration
75
80
85
ms
7
‘On Hook mode’ Accept CAS Duration
75
-
-
ms
8
CAS Detection Delay from Start of CAS
tDET1
60
-
-
ms
See Figure 13
9
CAS Detection Delay from End of CAS No speech
tDET2
-
-
15
ms
See Figure 13
10
CAS Detection Indicator Pulse Width
tDW
415
416
417
µs
See Figure 13
1, 3, 4
†AC Electrical Characteristics are over recommended operating conditions, unless otherwise stated.
‡Typical figures are at 25˚C and are for design aid only: not guaranteed and not subject to production testing.
*Notes:
1.OSC1 frequency at 3.579545MHz ± 0.1%.
2.Tip/Ring or 4-wire side input signal level. Signal level is per tone.
dBm = decibels above or below a reference power of 1mW into 600 ohms. 0dBm = 0.7746Vrms.
dBV = decibels above or below a reference voltage of 1Vrms. 0dBV = 1Vrms.
3.‘On Hook mode’: GS1 op-amp configured to 0dB gain for Vdd=5V±10%, -4dB (preliminary) for Vdd=3V±10%.
4.‘Off Hook mode’: GS2 op-amp configured to 0dB gain for Vdd=5V±10%, -4dB (preliminary) for Vdd=3V±10%.
5.When the signal level difference between the upper and lower tones is within the twist limits.
6.Test condition is both tones have the same amplitude.
15
MT88E46
Advance Information
AC Electrical Characteristics† - FSK Demodulation
Characteristics
Sym
1 Accept Signal Level
2 Bell 202 Format Reject Signal Level
3 Transmission Rate
4
Mark and Space Frequencies
Bell 202 1 (Mark)
Bell 202 0 (Space)
CCITT V.23 1 (Mark)
CCITT V.23 0 (Space)
Min
Typ‡
Max
-40
-37.78
10.0
-
-6.45
-4.23
476
-
-
-50.46 dBV
-48.24 dBm 1, 2, 3
3
mVrms
1188
1200
1212
baud
1188
2178
1200
2200
1212
2222
Hz
Hz
Units
dBV
dBm 1, 2
mVrms
1280.5 1300 1319.5
2068.5 2100 2131.5
5 Twist: 20 log (VMARK/VSPACE)
Notes*
Hz
Hz
-6
-
+10
dB
2
SNRFSK
20
-
-
dB
2, 3, 4
7 Input FSK to CD low delay
tCP
-
-
25
ms
See Figures 16, 17
8 Input FSK to CD high delay
tCA
10
-
-
ms
See Figures 16, 17
10
-
-
ms
6 Signal to Noise Ratio
9 CD Time Hysteresis
†AC Electrical Characteristics are over recommended operating conditions, unless otherwise stated.
‡Typical figures are at 25˚C and are for design aid only: not guaranteed and not subject to production testing.
*Notes:
1.Tip/Ring input signal level.
dBm = decibels above or below a reference power of 1mW into 600 ohms. 0dBm = 0.7746Vrms.
dBV = decibels above or below a reference voltage of 1Vrms. 0dBV = 1Vrms.
2.GS1 op-amp configured to 0dB gain for Vdd=5V±10%, -4dB (preliminary) for Vdd=3V±10%.
3.Both mark and space have the same amplitude.
4.Band limited random noise (300-3400Hz). Present when FSK signal is present.
Electrical Characteristics† - Gain Setting Amplifiers
Characteristics
Sym
Min
Max
Units
1
Input Leakage Current
IIN
-
1
µA
2
Input Resistance
RIN
10
-
MΩ
3
Input Offset Voltage
VOS
-
25
mV
4
Power Supply Rejection Ratio
PSRR
30
-
dB
1kHz ripple on Vdd
5
Common Mode Rejection Ratio
CMRR
40
-
dB
VCMmin ≤ VIN ≤ VCMmax
6
DC Open Loop Voltage Gain
AVOL
40
-
dB
7
Unity Gain Bandwidth
fC
0.3
-
MHz
8
Output Voltage Swing
VO
0.5
Vdd-0.7
V
9
Capacitive Load (GS1,GS2)
CL
-
50
pF
RL
100
-
kΩ
VCM
1.0
Vdd-1.0
V
10 Resistive Load (GS1,GS2)
11 Common Mode Range Voltage
†Electrical characteristics are over recommended operating conditions, unless otherwise stated.
16
Test Conditions
Vss ≤ VIN ≤ Vdd
Load ≥ 100kΩ
Advance Information
MT88E46
AC Electrical Characteristics† - Mode 0 FSK Data Interface Timing
Sym
Min
Typ‡
Max
Units
Rise time
tRR
-
-
200
ns
into 50pF load
See Figure 11
Fall time
tRF
-
-
200
ns
into 50pF load
See Figure 11
Low time
tRL
415
416
417
µs
1.
See Figs. 11, 14, 15
1188
1200
1212
baud
tIDD
-
1
5
ms
See Figure 14
Characteristics
1
2
DR
3
4
5
DATA
Rate
Input FSK to DATA delay
Notes*
2
6
Rise time
tR
-
-
200
ns
into 50pF load
See Figure 10
7
Fall time
tF
-
-
200
ns
into 50pF load
See Figure 10
DATA to DCLK delay
tDCD
6
416
-
µs
1, 2, 3
See Figure 10
9
DCLK to DATA delay
tCDD
6
416
-
µs
1, 2, 3
See Figure 10
10
Frequency
fDCLK0
1201.6
1202.8
1204
Hz
1. See Figure 14
High time
tCH
415
416
417
µs
1. See Figures 10, 14
Low time
tCL
415
416
417
µs
1. See Figures 10, 14
tCRD
415
416
417
µs
1. See Figure 14
8
11
DATA
DCLK
DCLK
12
13
DCLK
DR
DCLK to DR delay
†AC Electrical Characteristics are over recommended operating conditions, unless otherwise stated.
‡Typical figures are at 25˚C and are for design aid only: not guaranteed and not subject to production testing.
*Notes:
1.OSC1 at 3.579545 MHz ± 0.1%.
2.FSK input data at 1200 ± 12 baud.
3.Function of signal condition.
AC Electrical Characteristics† - Mode 1 FSK Data Interface Timing
Characteristics
1
2
5
Min
Max
Units
fDCLK1
-
1
MHz
30
70
%
tR1
-
100
ns
See Figure 12
DCLK low set up to DR
tDDS
500
-
ns
See Figure 15
DCLK low hold time after DR
tDDH
500
-
ns
See Figure 15
Frequency
DCLK
3
4
Sym
Duty cycle
Rise time
DCLK
DR
Notes
See Figure 15
†AC Electrical Characteristics are over recommended operating conditions unless otherwise stated.
AC Electrical Characteristics† - General Timing
Characteristics
1
2
OSC2
Sym
Min
Max
Units
Notes
Power-up time
tPU
-
50
ms
See Figures 16, 17
Power-down time
tPD
-
10
ms
See Figure 16
†AC Electrical Characteristics are over recommended operating conditions unless otherwise stated.
17
MT88E46
Advance Information
AC Electrical Characteristics - Timing Parameter Measurement Voltage Levels
Characteristics
Sym
Level
Units
1
CMOS Threshold Voltage
VCT
0.5*Vdd
V
2
Rise/Fall Threshold Voltage High
VHM
0.7*Vdd
V
3
Rise/Fall Threshold Voltage Low
VLM
0.3*Vdd
V
Notes
tCDD
tDCD
VHM
DATA
VCT
VLM
tF
tR
VHM
VCT
VLM
DCLK
tCL
tCH
tR
tF
Figure 10 - DATA and DCLK Mode 0 Output Timing
tRR
tRF
VHM
VCT
VLM
DR
tRL
Figure 11 - DR Output Timing
VHM
DCLK
VLM
tR1
Figure 12 - DCLK Mode 1 Input Timing
18
MT88E46
Advance Information
CAS
See ‘AC Electrical Characteristics CAS Detection’ for tDET1 and tDET2
values.
tDET2
DET
(Output)
tDET1
tDW = 416µs nominal
Figure 13 - CAS Detection Timing
start
start
TIP/RING
b7
stop
DATA
(Output)
b6 b7
b0 b1 b2 b3 b4 b5 b6 b7
start
b0 b1 b2 b3 b4 b5 b6 b7
stop
tIDD
start
b0 b1 b2 b3 b4 b5 b6 b7
stop
b0 b1 b2 b3 b4 b5
stop
start
start
b0 b1 b2 b3 b4 b5 b6 b7
stop
b0 b1 b2 b3
stop
DCLK
(Output)
tCL
tCH
tCRD
1/fDCLK0
DR
(Output)
tRL
Note: The relationship between DATA bit boundary and DCLK is symbolic only. In reality, the DATA bit boundary will jitter with
respect to the DCLK falling edges.
Figure 14 - FSK Data Interface Timing - Mode 0
Demodulated Data
(Internal Signal)
Word N+1
Word N
stop
7
1
0
start
2
3
4
5
Note 1
DR (Data Ready)
(Output)
6
7
stop
tRL
Note 2
>tDDS
>tDDH
1/fDCLK1
Note 3
DCLK (Data Clock)
(Schmitt Input)
DATA
(Output)
7
stop 0
Word N-1
1
2
3
4
5
6
7
stop
0
Word N
The DCLK input must be low before and after DR falling edge.
Note 1: DCLK occurs during DR low and returns DR to high.
Note 2: DCLK occurs after DR, so DR is low for half a nominal bit time.
Note 3: When framing error (trailing stop bit a 0 instead of a 1) is not checked, the microcontroller only needs to send 8 DCLK
pulses to shift the byte out.
Figure 15 - FSK Data Interface Timing - Mode 1
19
MT88E46
TIP/RING
Advance Information
1st Ring
PWDN
(Note 1)
Ch. seizure
B
A
C
Mark
D
Data
2nd Ring
F
E
Note 2
Note 3 Note 2
tPU
Note 4
tPD
OSC2
FSKen
(Note 1)
tCP
tCA
CD
DR
(Note 5)
DCLK
DATA
..101010..
Data
A = 2sec typical
B = 250-500ms
C = 250ms
D = 150ms
E = feature specific
Max C+D+E = 2.9 to 3.7sec
F ≥ 200ms
Figure 16 - Application Timing: Bellcore On-Hook Data Transmission Associated with Ringing, e.g.
Calling Number Delivery, Calling Name Delivery
Notes:
This on-hook case application is included because a CIDCW CPE must also be capable of receiving on-hook data transmission (with
ringing) from the central office.
1)PWDN and FSKen are internal signals decoded from CB0/1/2.
2)The CPE designer may choose to enable the MT88E46 only after the end of ringing to conserve power in a battery operated CPE.
CD is not activated by ringing.
3)The microcontroller in the CPE powers down the MT88E46 after CD has become inactive.
4)The microcontroller times out if CD is not activated.
5)The DR/DET output pin is the DR signal when FSK is selected.
20
Advance Information
CPE goes off-hook
CPE mutes handset, disables keypad
and performs MEI check (See TIA/EIA-777)
MT88E46
CPE unmutes handset
and enables keypad
CPE sends
TIP/RING
CAS
A
PWDN
(Note 6)
C
B
25ms
Note 1
Mark
ACK
D
Note 5
E
Speech
Data
F
G
30-40ms
Off Hook CASen
(Note 6)
FSKen
(Note 6)
Note 2
Note 3
Note 4
tCP
tCA
tPU
OSC2
tDET2
DET
(Note 7)
tDW
CD
DR
(Note 7)
DCLK
DATA
Data
A = 75-85ms
B = 0-100ms
C = 55-65ms
D = 0-500ms
E = 58-75ms
F = feature specific
G ≤ 50ms
Figure 17 - Application Timing: Bellcore Off-Hook Data Transmission, e.g. CIDCW
Notes:
1)In a CPE where AC power is not available, the designer may choose to switch over to line power when the CPE goes off-hook and
use battery power while on-hook. The CPE must also be CID (on-hook) capable because a CIDCW CPE includes CID functionality.
2)Non-FSK signals such as CAS, speech and DTMF tones are in the same frequency band as FSK. They will be demodulated and give
false data. Therefore the MT88E46 should be taken out of FSK mode when FSK is not expected.
3)If the CPE is the ACK-Sender, the MT88E46 may be put into FSK mode right after ACK has been sent. If the CPE is not the ACKSender, the MT88E46 should be put into FSK mode at 30ms (min ACK delay) + 55ms (min ACK duration) = 85ms after the line
HIGH transition. In that case the FSK carrier detector may be activated by the ACK if both the ACK delay and the ACK duration are
at maximum. TR-NWT-000575 specifies that ACK = DTMF ‘D’ for non-ADSI CPE, ‘A’ for ADSI CPE.
4)The MT88E46 should be taken out of FSK mode when CD has become inactive, or when more than 5 framing errors have been
detected in the message, or when more than 150ms of continuous Mark or Space has been detected.
5)In an unsuccessful attempt where the central office does not send the FSK signal, the CPE should unmute the handset and enable
the keypad after interval D has expired.
6)PWDN, Off Hook CASen and FSKen are internal signals decoded from CB0/1/2.
7)The DR/DET output pin is the DET signal when CAS detection is selected, the DR signal when FSK is selected.
21
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