®
ISO
2
-CMOS
MT9196
Integrated Digital Phone Circuit (IDPC)
Preliminary Information
Features
•
•
•
•
•
•
•
•
•
•
Programmable
µ-Law/A-Law
CODEC and
Filters
Programmable CCITT (G.711)/sign-magnitude
coding
Programmable transmit, receive and side-tone
gains
Digital DTMF and single tone generation
Fully differential interface to handset
transducers
Auxiliary analog interface
Interface to ST-BUS/SSI (compatible with GCI)
Serial microport control
Single 5 volt supply, low power operation
Anti-howl circuit for group listening
speakerphone applications
ISSUE 3
May 1995
Ordering Information
MT9196AE
28 Pin Plastic DIP
MT9196AP
28 Pin Plastic LCC
MT9196AS
28 Pin SOIC
-40°C to +85°C
Description
The MT9196 Integrated Digital Phone Circuit (IDPC)
is designed for use in digital phone products. The
device incorporates a built-in Filter/Codec, digital
gain pads, DTMF generator and tone ringer.
Complete telephony interfaces are provided for
connecting
to
handset
and
speakerphone
transducers. Internal register access is provided
through a serial microport compatible with various
industry standard micro-controllers.
The device is fabricated in Mitel's ISO
2
-CMOS
technology ensuring low power consumption and
high reliability.
Applications
•
•
•
Digital telephone sets
Wireless telephones
Local area communications stations
VSSD
VDD
VSSA
VSS SPKR
VBias
VRef
Tone Generator
Digital Gain &
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24dB
21/ -
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∆3.0dB
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Tx & Rx
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Filter/Codec Gain
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Encoder
7dB
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Decoder
-7dB
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AUXin
AUXout
MIC +
M-
M+
Transducer
Interface
HSPKR +
HSPKR -
Din
Timing
Dout
STB/F0i
CLOCKin
Serial Microport
XSTL2
IC
IRQ
CS
DATA1
DATA2
SCLK
Flexible
Digital
Interface
SPKR +
SPKR -
ST-BUS
C&D
Channels
WD
PWRST
Figure 1 - Functional Block Diagram
7-127
MT9196
M+
M-
VSSA
MIC+
AUXin
Preliminary Information
VRef
VBias
PWRST
IC
VSSD
CS
SCLK
DATA1
DATA2
4 3 2 1 28 27 26
5
25
24
6
23
7
22
8
21
9
20
10
19
11
12 13 14 15 16 17 18
AUXout
VSS SPKR
SPKR+
SPKR-
HSPKR+
HSPKR-
VDD
WD
IRQ
Dout
Din
STB/F0i
CLOCKin
XSTAL2
M-
M+
VBias
VRef
PWRST
IC
VSSD
CS
SCLK
DATA1
DATA2
WD
IRQ
Dout
1
2
3
4
5
6
7
8
9
10
11
12
13
14
28
27
26
25
24
23
22
21
20
19
18
17
16
15
VSSA
MIC+
AUXin
AUXout
VSS SPKR
SPKR+
SPKR-
HSPKR+
HSPKR-
VDD
XSTAL2
CLOCKin
STB/F0i
Din
28 PIN PLCC
28 PIN SOIC/PDIP
Figure 2 - Pin Connections
Pin Description
Pin #
1
2
3
4
5
6
7
8
9
10
Name
M-
M+
V
Bias
V
Ref
PWRST
IC
V
SSD
CS
SCLK
DATA1
Description
Inverting Microphone (Input).
Inverting input to microphone amplifier from the handset
microphone.
Non-Inverting Microphone (Input).
Non-inverting input to microphone amplifier from the
handset microphone.
Bias Voltage (Output).
(V
DD
/2) volts is available at this pin for biasing external amplifiers.
Connect 0.1 µF capacitor to V
SSA
.
Reference voltage for codec (Output).
Nominally [(V
DD
/2)-1.5] volts. Used internally.
Connect 0.1 µF capacitor to V
SSA
.
Power-up Reset (Input).
CMOS compatible input with Schmitt Trigger (active low).
Internal Connection.
Tie externally to V
SS
for normal operation.
Digital Ground.
Nominally 0 volts.
Chip Select (Input).
This input signal is used to select the device for microport data
transfers. Active low. TTL level compatible.
Serial Port Synchronous Clock (Input).
Data clock for microport. TTL level compatible.
Bidirectional Serial Data.
Port for microprocessor serial data transfer. In Motorola/National
mode of operation, this pin becomes the data transmit pin only and data receive is
performed on the DATA2 pin. TTL level compatible input levels.
Serial Data Receive.
In Motorola/National mode of operation, this pin is used for data
receive to the IDPC. In Intel mode, serial data transmit and receive are performed on the
DATA1 pin and DATA2 is disconnected. Input level TTL compatible.
Watchdog (Output).
Watchdog timer output. Active high.
Interrupt Request (Open Drain Output).
Low true interrupt output to microcontroller.
Data Output.
A tri-state digital output for 8 bit wide channel data being sent to the Layer 1
device. Data is shifted out via this pin concurrent with the rising edge of BCL during the
timeslot defined by STB, or according to standard ST-BUS timing.
Data Input.
A digital input for 8 bit wide channel data received from the Layer 1 device.
Data is sampled on the falling edge of BCL during the timeslot defined by STB, or according
to standard ST-BUS timing. Input level is CMOS compatible.
11
DATA2
12
13
14
WD
IRQ
D
out
15
D
in
7-128
Preliminary Information
Pin Description (continued)
Pin #
16
Name
STB/F0i
Description
MT9196
Data Strobe/Frame Pulse (Input).
For SSI mode this input determines the 8 bit timeslot
used by the device for both transmit and receive data. This active high signal has a
repetition rate of 8 kHz. Standard frame pulse definitions apply in ST-BUS mode. CMOS
level compatible input.
17
CLOCKin
Clock Input.
The clock provided to this input is used by the internal phone functions. In ST-
BUS mode this is the C4i input. In SSI synchronous mode, this is the Bit Clock input. In
SSI-asynchronous mode this is an asynchronous 4 MHz Master Clock input.
XSTL2
V
DD
Crystal Input (4.096 MHz).
Used in conjunction with the CLOCKin pin to provide the master
clock signal via external crystal.
Positive Power Supply (Input).
Nominally 5 volts.
18
19
20
21
22
23
24
25
26
27
28
HSPKR-
Inverting Handset Speaker (Output).
Output to the handset speaker (balanced).
HSPKR+
Non-Inverting Handset Speaker (Output).
Output to the handset speaker (balanced).
SPKR-
SPKR+
Inverting Speaker (Output).
Output to the speakerphone speaker (balanced).
Non-Inverting Speaker (Output).
Output to the speakerphone speaker (balanced).
V
SS
SPKR
Power Supply Rail for Speaker Driver.
Nominally 0 Volts.
AUX
out
AUX
in
MIC+
V
SSA
Auxiliary Port (Output).
Access point to the D/A (analog) signals of the receive path as
well as to the various analog inputs.
Auxiliary Port (Input).
An analog signal may be fed to the filter/codec transmit section and
various loopback paths via this pin. No external anti-aliasing is required.
Non-inverting on-hook answer back Microphone (Input).
Microphone amplifier non-
inverting input pin.
Analog Ground (Input).
Nominally 0 V.
7-129
MT9196
Overview
The functional block diagram of Figure 1 depicts the
main operations performed by the MT9196 IDPC.
Each of these functional blocks will be described
individually in the sections to follow. This overview
will describe some of the end-user features which
may be implemented as a direct result of the level of
integration found within the IDPC.
The main feature required of a digital telephone is to
convert the digital Pulse Code Modulated (PCM)
information, being received by the telephone set, into
an analog electrical signal. This signal is then
applied to an appropriate audio transducer such that
the information is finally converted into intelligible
acoustic energy. The same is true of the reverse
direction where acoustic energy is converted first
into an electrical analog and then digitized (into
PCM) before being transmitted from the set. Along
the way if the signals can be manipulated, either in
the analog or the digital domains, other features
such as gain control and signal generation may be
added. Finally, most electro-acoustic transducers
(loudspeakers) require a large amount of power if
they are to develop an acoustic signal. The inclusion
of audio amplifiers to provide this power is required.
The IDPC features complete Analog/Digital and
Digital/Analog conversion of audio signals (Filter/
CODEC) and an analog interface to electro-acoustic
devices (Transducer Interface). Full programmability
of the receive path and side-tone gains is available
to set comfortable listening levels for the user.
Transmit path gain control is available for setting
nominal transmit levels into the network. A digital,
anti-feedback circuit permits both the handset
microphone and the speaker-phone speaker to be
enabled at the same time for group listening
applications. This anti-feedback circuit limits the
total loop gain there by preventing a singing
condition from developing.
Signalling in digital telephone systems, behind the
PBX or standard ISDN applications, is handled on
the D-channel and generally does not require DTMF
tones. Locally generated tones, in the set, however,
can be used to provided “comfort tones” or “key
confirmation” to the user, similar to the familiar
DTMF tones generated by conventional phones
during initial call set-up. Also, as the network slowly
evolves from the dial pulse/DTMF methods to the D-
Channel protocols it is essential that the older
methods be available for backward compatibility. As
an example, once a call has been established (i.e.,
from your office to your home) using the D-Channel
Preliminary Information
signalling protocol it may be necessary to use in-
band DTMF signalling to manipulate your personal
answering machine in order to retrieve messages.
Thus the locally generated tones must be of network
quality. The IDPC can generate the required tone
pairs as well as single tones to accommodate any in-
band signalling requirement.
Each of the programmable parameters within the
functional blocks is accessed through a serial
microcontroller port compatible with Intel MCS-51
®
,
Motorola SPI
®
and National Semiconductor
Microwire
®
specifications.
Functional Description
In this section each of the functional blocks within
IDPC is described along with all of the associated
control/status bits. Each time a control/status bit(s) is
described it is followed by the address register
where it will be found. The reader is referred to the
section titled 'Register Summary' for a complete
listing of all address registers, the control/status bits
associated with each register and a definition of the
function of each control/status bit. The Register
Summary is useful for future reference of control/
status bits without the need to locate them in the text
of the functional descriptions.
Filter/CODEC
The Filter/CODEC block implements conversion of
the analog 3.3 kHz speech signals to/from the digital
domain compatible with 64 kb/s PCM B-Channels.
Selection of companding curves and digital code
assignment are register programmable. These are
CCITT G.711 A-law or
µ-Law,
with true-sign/
Alternate Digit Inversion or true-sign/Inverted
Magnitude coding, respectively. Optionally, sign-
magnitude coding may also be selected for
proprietary applications.
The Filter/CODEC block also implements transmit
and receive audio path gains in the analog domain.
These gains are in addition to the digital gain pad
section and provide an overall path gain resolution of
1.0dB. A programmable gain, voice side-tone path is
also included to provide proportional transmit speech
feedback to the handset receiver. Figure 3 depicts
the nominal half-channel and side-tone gains for the
IDPC.
Intel® and MCS-51® are registered trademarks of Intel Corporation
Motorola® and SPI® are registered trademarks of Motorola Corporation
National® and Microwire® are trademarks of National Semiconductor Corporation
7-130
Preliminary Information
On PWRST (pin 5) the Filter/CODEC defaults such
that the side-tone path, dial tone filter and 400 Hz
transmit filter are off, all programmable gains are set
to 0dB and CCITT
µ-Law
is selected. Further, the
Filter/CODEC is powered down due to the control
bits of the Path Control Registers (addresses 12h
and 13h) being reset.
The internal architecture is fully differential to provide
the best possible noise rejection as well as to allow a
wide dynamic range from a single 5 volt supply
design. This fully differential architecture is
continued into the Transducer Interface section to
provide full chip realization of these capabilities for
the handset and loudspeaker functions.
A reference voltage (V
Ref
), for the conversion
requirements of the CODEC section, and a bias
voltage (V
Bias
), for biasing the internal analog
sections, are both generated on-chip. V
Bias
is also
brought to an external pin so that it may be used for
biasing external gain plan setting amplifiers. A 0.1 µF
SERIAL
PORT
DIGITAL GAIN
& TONES
FILTER/CODEC
MT9196
capacitor must be connected from V
Bias
to analog
ground at all times. Likewise, although V
Ref
may only
be used internally, a 0.1 µF capacitor from the V
Ref
pin to ground is required at all times. The analog
ground reference point for these two capacitors must
be physically the same point. To facilitate this the
V
Ref
and V
Bias
pins are situated on adjacent pins.
The transmit filter is designed to meet CCITT G.714
specifications. The nominal gain for this filter path is
0 dB (gain control = 0 dB). Gain control allows the
output signal to be increased up to 7 dB. An anti-
aliasing filter is included. This is a second order
lowpass implementation with a corner frequency at
25 kHz. Attenuation is better than 32 dB at 256 kHz
and less than 0.01 dB within the passband.
An optional 400Hz high-pass function may be
included into the transmit path by enabling the Tfhp
bit in the Control Register 1 (address 0Eh). This
option allows the reduction of transmitted
background noise such as motor and fan noise.
TRANSDUCER INTERFACE
-6.1 dB or
-3.6 dB
HSPKR +
Handset
Receiver
(150Ω)
Receive
PCM
D
in
-24 to
+21 dB
(3dB steps)
Receive
Filter Gain
0 to -7 dB
(1 dB steps)
-6 dB
Receiver
Driver
75
HSPKR -
75
Side-tone
-9.96 to
+9 96dB
(3.32 dB steps)
DTMF,
Tone
Ringer
-11 dB
Speaker
Phone
Driver
0 dB
SPKR +
SPKR -
0/+8dB
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A
A
+8 to -20dB
(4 dB steps)
RINGER
0 to -28 dB
(4 dB steps)
Auxiliary
Out
Driver
-12 dB
AUXout
Speakerphone
Speaker
(40Ω nominal)
34Ω min)
PCM
D
out
-24 to
+21 dB
(3 dB steps)
Transmit
Transmit Filter
Gain
0 to +7 dB
(1 dB steps)
Trans-
mit
Gain
-0.37 dB
or 8.93 dB
Trans-
mit
Gain
6.37 dB
5 dB
M
U
X
5 dB
AUXin AUX input
MIC+
H/F answer-
back mic
M + Transitter
microphone
M-
Digital Domain
Analog Domain
Internal To Device
External To Device
Figure 3 - Audio Gain Partitioning
7-131
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