MITEL MT8965AE, MT8966AS, MT8964AE, MT8963AE, MT8963AS Datasheet

2



ISO

-CMOS

MT8960/61/62/63/ 64/65/66/67

Integrated PCM Filter Codec

Features

•ST-BUS compatible

• Transmit/Rec eive f ilters & PCM Codec i n on e
I.C

• Meets AT&T D3/D4 and CC ITT G7 11 and G712

• µ-Law: MT8960/62/64/67

• A-Law: MT8961/63/65/67

• Low power co nsu mpt ion:

Op.: 30 mW typ.
Stby.: 2.5 mW typ.

• Digital Codi ng Opti ons :
MT8964/65/66/67 CCITT Code

MT8960/61/62/63 Alternative Code

• Digitally cont rolled gain ad jus t of both f ilters

• Analog and digi tal loop bac k

• Filters and c odec in depen de ntly us er
accessible for testing

• Powerdown mode available

• 2.048 MHz master clock input

• Up to six uncommitted control outputs

• ±5V ±5% power s upp ly

ISSUE 10 May 1995

Ordering Information

MT8964/65AC 18 Pin Ceramic DIP
MT8960/61/64/65AE 18 Pin Plastic DIP
MT8962/63AE 20 Pin Plastic DIP
MT8962/63/66/67AS 20 Pin SOIC

0°C to+ 70°C

Descript io n

Manufac tured in IS O2-CMOS, these integrated filter/
codecs are designed to meet the demanding
performance needs of the digital telecommunications
industry, e.g., PABX, Central Office, Digital
telephones.

ANUL

V

SD0
SD1
SD2
SD3
SD4
SD5

V

R

X

Transmit

Filter

Output

Register

Receive

Filter

V

Ref

Analog to

Digital PCM

Encoder

A Register

B-Register

PCM Digita l

to Analog

Decoder

GNDA GNDD V

8-Bits

8-Bits

DDVEE

Output

Register

Control

Logic

Input

Register

DSTo

CSTi
CA

F1i
C2i

DSTi

Figure 1 - Functional Block Diagram

6-19

MT8960/61/62/63/64/65/66/67 ISO

2

-CMOS

MT8960/61/64/65

CSTi
DSTi

DSTo

VDD

SD3
SD2

1
2

3

C2i

4
5

F1i

6

CA

7
8
9

18 PIN CERDIP/PDIP

18
17
16
15
14
13
12
11
10

GNDD
VRef
GNDA
VR
ANUL
VX
VEE
SD0
SD1

CSTi
DSTi

DSTo

VDD

MT8962/63/66/67

1
2

3

C2i

4

5
SD5
SD4

SD3

6

7

F1i

8

CA

9

10

20 PIN PDIP/SOIC

20
19
18
17
16
15
14
13
12
11

GNDD
VRef
GNDA
VR
ANUL
VX
VEE
SD0
SD1
SD2

Figure 2 - Pin Conne ctions

Pin Description

Pin Name Description

CSTi Control ST-BUS In is a TTL-compa tib le digit al inpu t used to control the functi on of the filter/cod ec.

Three modes of operation may be effect ed by applying to this input a logic high (V
(GNDD), or an 8-bit serial word, depending on the logic states of CA and F1i

.

Functions controlled are : powerdown, filter gain adjust, loopba ck, chip testing, SD outputs.

DSTi Data ST-BUS In accepts the incoming 8-bit PCM word. Input is TTL-compatible.

), logic low

DD

C2i Clock Input is a TTL-compatible 2.048 MHz clock.

DSTo Data ST-BUS Out is a three-state digital output driving the PCM bus with the outgoing 8-bit PCM

word.

V

F1i

Positi ve pow er Supp ly (+5V).

DD

Synchronization Input is an active low digital input enabling (in conjunction with CA) the PCM input,

PCM output and digital cont rol input . It is internally sampled on every positive edge of the clock, C2i,
and provides f rame and channel synchronization.

CA Control Address is a three-level digit al input which enabl es PCM input and output and determine s

into which control register (A or B) the serial data, presented to CSTi, is stored.

SD3 System Drive Output is an open drain output of an N-channel transistor which has its source tied to

GNDA. Inactive stat e is open circui t.

SD4-5 System Drive Outputs

are open drain outputs of N-channel transistors which have their source tied

to GNDD. Inactive state is open circuit.

SD0-2 System Drive Outputs

are “Totempole“ CMOS output s switching between GNDD and V

. Inactive

DD

state is logic low.

V

V

ANUL Auto Nul l

Negative power supply (-5V).

EE

Voice Transmit is the analog input to the transmit filter.

X

is used to integrate an internal auto-null signal. A 0.1µF capacitor must be connected

between this pin and GNDA.

V

Voice Receive is the analog output of the receive filter.

R

GNDA Analog ground (0V).

V

Vo ltag e Reference input to D to A converter.

Ref

GNDD Digital grou nd (0V ).

6-20

ISO

2

-CMOS MT8960/61/62/63/64/65/66/67

MT8960/62

Digital Ou tput

11111111
11110000
11100000
11010000
11000000
10110000
10100000
10010000

10000000
00000000
00010000

00100000
00110000
01000000
01010000
01100000
01110000
01111111

Bit 7... 0
MSB LSB

-2.415V -1.207V 0V +1.207V +2.415V
Analog Input Voltage (V

)

IN

MT8964/66

Digital Output

10000000
10001111
10011111
10101111
10111111
11001111
11011111
11101111

11111111
01111111
01101111

01011111
01001111
00111111
00101111
00011111
00001111
00000000

Figure 3 - µ-Law Encoder Transfer Characteristic

MT8961/63

Digital Ou tput

11111111
11110000
11100000
11010000
11000000
10110000
10100000
10010000

10000000
00000000
00010000

00100000
00110000
01000000
01010000
01100000
01110000
01111111

-2.5V -1. 25 V 0V

+1.25V

MT8965/67

Digital Output

+2.5 V

1010 1010
1010 0101
1011 0101
1000 0101
1001 0101
1110 0101
1111 0101
1100 0101

1101 0101
0101 0101
0100 0101

0111 0101
0110 0101
0001 0101
0000 0101
0011 0101
0010 0101
0010 1010

Bit 7... 0
MSB LSB

Analog Input Voltage (V

)

IN

Figure 4 - A-L aw E ncod er Transfer Char ac teristi c

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MT8960/61/62/63/64/65/66/67 ISO

2

-CMOS

Functional Description

Figure 1 shows the functional block diagram of the
MT8960-67. These devices provide the conversion
interface between the voiceband analog signals of a
telephone subscriber loop and the digital signals
required in a digital PCM (pulse code modulation)
switching system. Analog (voiceband) signals in the
transmit path enter the chip at V
8kHz, and the samples quantized and assigned 8-bit
digital values defined by logarithmic PCM encoding
laws. Analog signals in the receive path leave the
chip at V
words.

Separate switched capacitor filt er sections are used
for bandlimiting prior to digital encoding in the
transmit path and after digital decoding in the receive
path. All filter clocks are derived f rom the 2.048 MHz
master clock input, C2i. Chip size is minimized by
the use of common circuitry performing the A to D
and D to A conversion. A successive approximation
technique is used with capacitor arrays t o define the
16 steps and 8 chords in the signal conversion
process. Eight-bit PCM encoded digital data enters
and leaves the chip serially on DSTi and DSTo pins,
respectively.

after reconstruction from digital 8-bit

R

, are sampled at

X

are 30 dB for 0-60 Hz and 35 dB for 4.6 kHz and
above.

The filter output signal is an 8 kHz staircase
waveform which is fed into the codec capacitor ar ray,
or alternatively, into an external capacitive load of
250 pF when the c hip is in the test mode. The digital
encoder generates an eight-bit digital word
representation of the 8 kHz sampled analog signal.
The first bit of serial data stream is bit 7 (MSB) and
represents the sign of the analog signal. Bits 4-6
represent the chord which contains the analog
sample value. Bits 0-3 represent the step value of
the analog sample within the selected chord. The
MT8960-63 provide a sign plus magnitude PCM
output code format. The MT8964/66 PCM output
code conforms to the AT &T D3 specification, i.e.,
true sign bit and inverted magnitude bits. The
MT8965/67 PCM output code conforms to the CCITT
specifications with alternate digit inversion (even bits
inverted). See Figs. 3 and 4 for the digital output
code corresponding to the analog voltage, V
input.

The eight-bit digital word is output at DSTo at a
nominal rate of 2.048 MHz, via the output buffer as
the first 8-bit s of the 125 µs sampling frame.

IN

, at V

X

Tra n smit Path

Analog signals at the input (Vx) are firstly
bandlimited to 508 kHz by an RC lowpass filter
section. This performs the necessary anti-aliasing
for the following first-order sampled data lowpass
pre-filter which is clocked at 512 kHz. This further
bandlimits the signal to 124 kHz before a fifth-order
elliptic lowpass filter, clocked at 128 kHz, provides
the 3.4 kHz bandwidth required by the encoder
section. A 50/60 Hz third-order highpass notch filter
clocked at 8 kHz completes the transmit filter pat h.
Accumulated DC offset is cancelled in this last
section by a switched-capacitor auto-zero loop which
integrates the sign bit of th e encoded PCM word, fed
back from the codec and injects this voltage level
into the non-inverting input of the comparator. An
integrating capacitor (of value between 0.1 and 1 µF)
must be externally connected from this point (ANUL)
to the Analog Ground (GNDA).

The absolute gain of the transmit filter (nominally 0
dB at 1 kHz) can be adjusted from 0 dB to 7 dB in 1
dB steps by means of three binary controlled gain
pads.

Receive P ath

An eight-bit PCM encoded digital word is received on
DSTi input once during the 125 µs period and is
loaded into the input register. A charge proportional
to the received PCM word appears on the capacitor
array and an 8 kHz sample and hold circuit
integrates this charge and holds it for the rest of the
sampling period.

The receive (D/A) filter provides interpolation filtering
on the 8 kHz sample and hold signal from the codec.
The filter consists of a 3.4 kHz lowpass fifth-order
elliptic section clocked at 128 kHz and performs
bandlimiting and sm oothing of the 8 kHz "staircase"
waveform. In addition, sinx/x gain correction is
applied to the signal to compensate for the
attenuation of higher frequencies caused by the
capacitive sample and hold circuit. The absolute
gain of the receive f ilter can be adjusted from 0 dB to

-7 dB in 1 dB steps by means of three binary
controlled gain pads. The resulting lowpass
characteristics, with the limits shown in Figure 11,
meet the CCITT and AT & T recommended
specifications.

The resulting bandpass characteristics with the limits
shown in Figure 10 meet the CCITT and AT&T
recommended specifications. Typical atttenuations

6-22

Typical attenuation at 4.6 kHz and above is 30 dB.
The filter is followed by a buffer amplifier which
will drive 5V peak/peak into a 10k ohm load, suitable
for driving electronic 2-4 wire circuits.

ISO

2

-CMOS MT8960/61/62/63/64/65/66/67

V

Ref

An external voltage must be supplied to the V

Ref

pin
which provides the reference voltage for the digital
encoding and decoding of the analog signal. For
V

= 2.5V, the digital encode decision value for

Ref

overload (maximum analog signal detect level) is
equal to an analog input V

= 2.415V (µ-Law

IN

version) or 2.5V (A-Law version) and is equivalent to
a signal level of 3.17 dBm0 or 3.14 dBm0
respectively, at the cod ec .

The analog output voltage from the decoder at V

is

R

defined as:

µ-Law:

C

V

Ref

X

-0.5 2

[( 128 )+( 128 )( 33 )]

16.5 + S

V

±

OFFSET

A-Law:
2

V

X

Ref

V

X

Ref

C+1

0.5 + S

[( 128 )( 32 )]

C

2

16.5 + S

[( 128 )( 32 )]

V

±

V

±

OFFSET

OFFSET

C=0

C≠0

driving a large number of codecs due to the high
input impedance of the V

input. Normal

Ref

precautions should be taken in PCB layout design to
minimize noise coupling to this pin. A 0.1 µF
capacitor connected from V

to ground and located

Ref

as close as possible to the codec is recommended to
minimize noise entering through V

. This capacitor

Ref

should have good high frequency characteristics.

Timing

The codec operates in a synchronous manner (see
Figure 9a). The codec is activated on the first
positive
digital output at DSTo (which is a three-state output
driver) will then change from a high impedance state
to the sign bit of the encoded PCM word to be
output. This will remain valid until the next positive
edge, when the next most significant bit will be
output.

On the first negative clock edge (after F1i signal has
been internally synchronized and CA is at GNDD or
V
into the input shift register as the sign bit of the
incoming PCM word.

edge of C2i af ter F1i has gone low. The

) the logic signal present at DSTi will be clocked

EE

where C = chord number (0-7)

S = step number (0-15)

is a high impedance input with a varying

V

Ref

capacitive load of up to 40 pF.

The recommended reference volt age for the MT8960
series of codecs is 2.5V ±0.5%. The output voltage
from the reference source should have a maximum
temperature coefficient of 100 ppm/C°. This voltage
should have a total regulation tolerance of ±0.5%
both for changes in the input voltage and output
loading of the voltage reference source. A voltage
reference circuit capable of meeting these
specifications is shown in Figure 5. Analog Devices
’AD1403A voltage reference circuit is capable of

NC

NC NC NC

5678

AD1403A

1234

The eight-bit word is thus input at DSTi on negative
edges of C2i and output at DSTo on positive edges
of C2i.

F1i

must ret urn to a high level after the eighth

clock pulse causing DSTo to enter high impedance

preven ti ng fur th e r input da ta to DS Ti. F1i will

and
continue to be sampled on every positive edge of
C2i. (Note: F1i

may subsequently be taken low
during the same sampling frame to enable entry of
serial data into CSTi. This occurs usually mid-frame,
in conjunction with CA=V

, in order to enter an 8-bit

DD

control word into Re g iste r B. In this case , PC M i n p ut
and output are inhibited by CA at V

V

Ref

0.1 µF

MT8960-67

FILTER/CODEC

DD

.)

+5V

NC

2.5V

Figure 5 - Typical Voltage Reference Circ uit

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MT8960/61/62/63/64/65/66/67 ISO

2

-CMOS

Internally the codec will then perform a decode cycle
on the newly input PCM word. The sampled and
held analog signal thus decoded will be updated 25
µs from the start of the c ycle. After this the analog
input from the filter is sample d for 18 µs, after wh ich
digital conversion takes place during the remaining
82 µs of the sampling cycle.

Since a single clock frequency of 2.048 MHz is
required, all digital data is input and output at this
rate. DSTo, therefore, assumes a high impedance
state for all but 3.9 µs of the 125 µs frame. Similarly,
DSTi input data is valid for only 3.9 µs.

Digital Control Functions

CSTi is a digital input (levels GNDD to VDD) which is
used to control the function of the filter/codec. It
operates in three different modes depending on the
logic levels applied to the Control Address input
(CA) and chip enable input (F1i

) (see Table 1).

Mode 1

CA= -5 V (VEE); CSTi=0V (GNDD)

Mode 2

CA= -5V (VEE); CSTi receives an eight-bit control
word

CSTi accepts a serial data stream synchronously
with DSTi (i.e ., it accept s an eight-b it serial wo rd in a

3.9 µs timeslot, updated every 125 µs, and is
specified identically to DSTi for timing
considerations). This eight-bit control word is
entered into Control Register A and enables
programming of the following functions: transmit and
receive gain, powerdown, loopback. Register B is
reset to zero and the SD outputs assume their
inactive state. Test modes cannot be entered.

Mode 3

CA=0V (GNDD); CSTi receives an eight-bit control
word

As in Mode 2, the control word enters Register A and
the aforementioned functions are controlled. In this
mode, however, Register B is not reset, thus not
affecting the states of the SD outputs.

The filter/codec is in normal operation with nominal
transmit and receive gain of 0dB. The SD outputs
are in their active states and the test modes cannot
be entered.

CA = -5V (V

A state of powerdown is forced upon the chip
whereby DSTo becomes high impedance, VR is
connected to GNDA and all analog sections have
power r em o ve d.

MODE CA CSTi FUNCTION

(Note 1)

(Note 2)

); CSTi = +5V (VDD)

EE

1

2V

3

V

EE

EE

GNDD Serial Eight-bit control word int o registe r A. Register B is unaffected.

V

DD

GNDD Norm al chip operation.

V

Serial Eight-bit control word into Register A. Register B is reset.

Data

Data

Serial Eight -bit control word int o registe r A. Register B is unaffected.

Data

DD

Powerdown.

CA=+5V (V

In this case the control word is transferred into
Register B. Register A is unaffected. The input and
output of PCM data is inhibited.

The contents of Register B controls the six
uncommitted outputs SD0-SD5 (four outputs, SD0­SD3, on MT8960/61/64/65 versions of chip) and also
provide entry into one of the three test modes of the
chip.

); CSTi receives an 8-bit control word

DD

Note 1: When operating in Mode 1, there should be only one frame pulse (F1i
Note 2: When operating in Mode 3, PCM input and output is inhibited by CA=V

Table 1. Digi ta l Con tr ol M o des

6-24

) per 125 µ s fra me

.

DD

2

ISO

-CMOS MT8960/61/62/63/64/65/66/67

Note: For Modes 1 and 2, F1i must be at logic low
for one period of 3.9 µs, in each 125 µs cycle, when
PCM data is being input and output, and the control
word at CSTi enters Register A. For Mode 3, F1i
must be at a logic low f or two periods of 3.9 µs, in
each 125 µs cycle. In the first period, CA must be at
GNDD or V
high (V

, and in the second period CA must be

EE

.

DD)

Control Registers A, B

BIT 2 BIT 1 BIT 0

FILTER GAIN (dB)

000 0
001 + 1
010 + 2
011 + 3
100 + 4

TRANSMIT (A/D)

The contents of these registers control the filter/
codec functions as described in Tables 2 and 3.

Bit 7 of the registers is the M SB and is defined as the
first bit of the serial data stream input (corresponding
to the sign bit of the PCM word).

On initial power-up these registers are set to the
powerdown condition for a maximum of 25 clock
cycles. During this time it is impossible to change
the data in these registers.

Chip Testing

By enabling Register B with valid data (eight-bit
control wor d in put to CSTi when F1i

) the chip testing mode can be entered. Bits 6

V

CC

=GNDD and CA=

and 7 (most sign bits) define states for testing the
transmit filter, receive filter and the codec function.
The input in each case is V
each case is V

output. (See Table 3 for details.)

R

input and the output in

X

Loopback

101 + 5
110 + 6
111 + 7

RECEIVE (D/A)

BIT 5 BIT 4 BIT 3

FILTER GAIN (dB)

000 0
001 - 1
010 - 2
011 - 3
100 - 4
101 - 5
110 - 6
111 - 7

BIT 7 BIT 6 FUNCTION CONTRO L

0 0 Normal operation
0 1 Digital Loopback

Loopback of the filter/codec is controlled by the
control word entered into Register A. Bits 6 and 7
(most sign bits) provide either a digital or analog
loopback condition. Digital loopback is defined as
follows:

• PCM input da ta at DS Ti is latche d in to the P CM
input regis ter an d the out put of this regis ter is
connected to the input of the 3-state PCM
output regist er.

• The digital input to the PCM digital-to-analog
decoder is d isco nnect ed, for ced to ze ro (0).

• The outpu t of the PCM encoder is di sabled and
thus the encoded data is lost . The PCM output
at DSTo is determined by the PCM input data.

Analog loopback is defined as follows:

• PCM input data is latched, decoded and filtered
as normal but not outp ut at V

.

R

1 0 Analog Loopback
1 1 Powerdown

Table 2. Con trol S tates - R eg ister A

• Analog o ut put buffer at V

has its input sh orted

R

to GNDA an d discon nec ted from the rec eive
filter output.

• Analog inp ut at V

is disconnec ted f rom the

X

transmit filter input.

• The receive filter output is connected to the
transmit fi lter inp ut. Th us the deco de sign al is
fed back th rough the rec ei ve path and en c od ed
in the normal way. The analog outp ut bu ffer at

is not tested by this configuration.

V

R

In both cases of loopback, DSTi

is the input

and DSTo is the output.

6-25