STMICROELECTRONICS M5913B1

M5913
COMBINED SINGLE CHIP PCM CODEC AND FILTER
SYNCHRONOUS CLOCKS ONLY
AT&T D3/D4 AND CCITT COMPATIBLE
TWO TIMING MODES:
FIXED DATA RATE MODE 1.536MHz,
1.544MHz, 2.048MHz
VARIABLE DATA MODE: 64KHz - 4.096MHz
PIN SELECTABLE µ-LAW OR A-LAW OPERATION
NO EXTERNAL COMPONENTS FOR SAMPLE-AND-HOLD AND AUTO ZERO FUNCTIONS
LOW POWER DISSIPATION:
0.5mW POWER DOWN
70mW OPERATING
EXCELLENT POWER SUPPLY REJECTION
DESCRIPTION
The M5913 is fully integrated PCM (pulse code
modulation) codecs and transmit/receive filter using CMOS silicon gate technology.
The primary applications for the M5913 are telephone systems :
- Switching - M5913-Digital PBX’s and Central
DIP 20
ORDERING NUMBER: M5913B1
Office Switching Systems
- Concentration - M5913 Subscriber Carrier and
Concentrators.
The wide dynamic range (78dB) and the minimal
conversion time make it ideal products for other
applications such as:
- Voice Store and Forward
- Secure Communications Systems
- Digital Echo Cancellers
- Satellite Earth Stations.
BLOCK DIAGRAM
December 1993
1/17
This is advanced information on a new product now in development or undergoing evaluation. Details are subject to change without notice.
M5913
ABSOLUTE MAXIMUM RATINGS
Symbol
VCC
Value
Unit
With Respect GRDD, GRDA = 0V
Parameter
– 0.6 to 7
V
With Respect GRDD, GRDA = 0V
- 0.6 to – 7
V
GRDD, GRDA
In Such Case : 0 ≤ VCC ≤ + 7V, – 7V ≤ VBB ≤ 0V
± 0.3
V
VI/O
Analog Inputs, Analog Outputs and Digital Inputs
VBB – 0.3 ≤ VIN/VOUT ≤ VCC +
0.3
V
VBB
VO DIG
Digital Outputs
Ptot
Total Power Dissipation
Tstg
Storage Temperature Range
GRDD – 0.3 ≤ VOUT ≤ VCC + 0.3
V
1
W
-65 to 150
°C
PIN CONNECTION (Top view)
PIN NAMES
Symbol
VBB
PWRO+, PWRO-
Power Amplifier Outputs
GSR
Gain Setting Input for receive Channel
PDN
CLKSEL
Symbol
Parameter
GSX
Gain Control
VFXI-, VFXI+
Analog Inputs
GRDA
Analog Ground
Power Pown Select
NC
No Connected
Master Clock Select
SIG X
Transmit Digital Signaling Input
LOOP
Analog Loop Back
ASEL
µ or A-law Select
SIG R
Signaling Bit Output
DCLKR
Receive Data Rate Clock
TSX
DCLKX
Digital Output - Timeslot Strobe
Transmit Data Rate Clock
DR
Receive Channel Input
DX
Transmit (Digital) Output
FSR
Receive Frame Synchronization Clock
FSX
Transmit Frame Synchronization Clock
GRDD
VCC
2/17
Parameter
Power (-5V)
Digital Ground
CLKX
Transmit Master Clock
Power (+5V)
CLKR
Receive Master Clock
M5913
PIN DESCRIPTION
Symbol
VBB
Function
Most Negative Supply. Input voltage is -5 volts ±5%.
PWRO+
Non-inverting Output of Power Amplifier. Can drive transformer hybrids or high impedance loads
directly in either a differential or single ended configuration.
PWRO -
Inverting Output of Power Amplifier. Functionally identical and complementary to PWRO+.
GSR
Input to the gain Setting Network on the Output Power Amplifier, Transmission level can be
adjusted over a 12dB range depending on the voltage at GSR.
PDN
Power Down Select. When PDN is TTL high, the device is active.When low, the device is powered
down.
CLKSEL
input which must be pinstrapped to reflect the master clock frequency at CLKX, CLKR.
CLKSEL = VBB
2.048MHz
CLKSEL = GRDD
1.544MHz
CLKSEL = VCC
1.536MHz
LOOP
Analog Loopback. When this pin is TTL high, the receive output (PWRO+) is internally connected
to VFXI+, GSR is internally connected to PWRO-, and VFXI- is internally connected to GSX.
A 0dBm0 digital signal input at DR is returned as a +3dBm0 digital signal output at DX.
SIGR
Signalling Bit Output, Receive Channel. In fixed data rate mode. SIGR outputs the logical state of
the eighth bit of the PCM word in the most recent signaling frame.
DCLKR
Selects the fixed or variable data rate mode. When DCLKR is connected to VBB, the fixed data rate
mode is selected.
When DCLKR is not connected to VBB, the device operates in the variable data rate mode. In this
mode DCLKR becomes the receive data clock wich operates at TTL levels from 64kB to 4.096MB
data rates
DR
Receive PCM Input. PCM data is clocked in on this lead on eight consecutive negative transitions
of the receive data clock: CLKR in the fixed data rate mode and DCLKR in variable data rate mode.
FSR
8kHz frame synchronization clock input/timeslot enable, receive channel. A multifunction input
which in fixed data rate mode distinguishes between signaling and non-signaling frames by means
of a double or single wide pulse respectively. In variable data rate mode this signal must remain
high for the entire length of the timeslot. The receive channel enters the standby state whenever
FSR is TTL low for 30 miliseconds
GRDD
Digital Ground for all Internal Logic Circuits. Not internally tied to GRDA.
CLKR
Receive master and data clock for the fixed data rate mode; receive master clock only in variable
data rate mode.
CLKX
Transmit master and data clock for the fixed data rate mode; transmit master clock only in variable
data rate mode.
FSX
8kHz frame synchronization clock input/timeslot enable, transmit channel. Operates independently
but in an analogous manner to FSR. The transmit channel enters the standby state whenever FSX
is TTL low for 30 milliseconds.
DX
Transmit PCM Output. PCM data is clocked out on this lead on eight consecutive positive
transitions of the transmit data clock : CLK in fixed data rate mode and DCLKX in variable data rate
mode.
TSX/DCLKX
Transmit channel timeslot strobe (output) or data clock (input) for the transmit channel. In fixed
data rate mode, this pin becomes the transmit data clock which operates at TTL levels from 64kB
to 4.096MB data rates.
SIG X/ASEL
A dual purpose selects µ-law and pin. When connected to VBB. A law operation is selected. When it
is not connected to VBB pin is a TTL level input for signaling operation. This input is transmitted as
the eighth bit of the PCM word during signaling frames on the DX lead.
NC
Not Connected.
GRDA
Analog ground return for all internal voice circuits. Not internally connected to GRDD.
VFXI+
Non inverting analog input to uncommitted transmit operational amplifier.
VFXI-
Inverting analog input to uncommitted transmit operational amplifier.
GSX
Output terminal of on-chip uncommitted op amp. Internally, this is the voice signal input to the
transmit filter.
VCC
Most positive supply ; input voltage is + 5 volts ±5%
3/17
M5913
FUNCTIONAL DESCRIPTION
The M5913 provides the analog-to-digital and the
digital-to-analog conversion and the transmit and
receive filtering necessary to interface a full duplex (4 wires) voice telephone circuit with the
PCM highway of a time division multiplexed
(TDM) system. It is intended to be used at the
analog termination of a PCM line.
The following major functions are provided :
Bandpass filtering of the analog signals prior to
encoding and after decoding
Encoding and decoding of voice and call progress information
Encoding and decoding of the signaling and
supervision information
GENERAL OPERATION
System Reliability Features
The combo-chip can be powered up by pulsing
FSX and/or FSR while a TTL high voltage is applied to PDN, provided that all clocks and supplies are connected. The M5913 has internal resets on power up (or when VBB or VCC are
re-applied) in order to ensure validity of the digital
outputs and thereby maintain integrity of the PCM
highway.
On the transmit channel, digital outputs DX and
TS X are held in a high impedance state for approximately four frames (500µs) after power up or
application of VBB or VCC. After this delay, DX and
TSX will be functional and will occur in the proper
timeslot. The analog circuits on the transmit side
require approximately 40 milliseconds to reach
their equilibrium value due to the autozero circuit
setting time. Thus, valid digital information, such
as for on/off hook detection, is available almost
immediately, while analog information is available
after some delay.
On the receive channel, the digital output SIGR is
also held low for a maximum of four frames after
power up or application of VBB or VCC, SIGR will
remain low thereafter until it is updated by a signaling frame.
To further enhance system reliability, TS X and DX
will be placed in a high impedance state approximately 20µs after an interruption of CLKX. Simi-
larly SIGR will be held low approximately 20µs after an interruption of CLKR. These interruptions
could possibly occur with some kind of fault condition.
Power Down And Standby Modes
To minimize power consumption, two power down
modes are provided in which most M5913 functions are disabled. Only the power down, clock,
and frame sync buffers, which are required to
power up the device, are enabled in these modes.
As shown in table 1, the digital outputs on the appropriate channels are placed in a high impedance state until the device returns to the active
mode.
The Power Down mode utilizes an external control signal to the PDN pin. In this mode, power
consumption is reduced to an average of 0.5mW.
The device is active when the signal is high and
inactive when it is low. In the absence of any signal, the PDN pin floats to TTL high allowing the
device to remain active continuously.
The Standby mode leaves the user an option of
powering either channel down separately or powering the entire down by selectively removing FSX
and/or FSR. With both channels in the standby
state, power consumption is reduced to an average of 1mW. If transmit only operation is desired,
FSX should be applied to the device while FSR is
held low. Similarly, if receive only operation is desired, FSR should be applied while FSX is held
low.
Fixed Data Rate Mode
Fixed data rate timing, is selected by connecting
DCLKR to VBB. It employs master clock CLKX, and
CLKR, frame synchronization clocks FSX and
FSR , and output TS X.
CLKX, and CLKR, serve both as the master clock
to operate the codec and filter sections and bit
clocks to clock the data in and out from the PCM
highway. FSX and FSR are 8kHz inputs which set
the sampling frequency and distinguish between
signaling and non-signaling frames by thir pulse
width. A frame synchronization pulse which is one
master clock wide designates a non-signaling
frame, while a double wide sync pulse enables
Table 1: Power Down Methods
Device Status
Power Down Methods
Digital Outputs Status
Power Down Mode
PDN = TTL low
TSX and DX are placed in a high impedance state and
SIG R is placed in a TTL low state within 10µs.
Stand-by Mode
FSX and FSR are TTL low
TSX and DX are placed in a high impedance state and
SIG R is placed in a TTL low state 30ms after FSX and
FSR are removed.
Only transmit is on stand-by
FSX is TTL low
TSX and DX are placed in a high impedance state
within 30ms.
Only receive is on stand-by
FSR is TTL low
SIG R is placed in a TTL low state within 30ms.
4/17
M5913
the signaling function. TSX is a timeslot
strobe/buffer enable output which gates the PCM
word onto the PCM highway when an external
buffer is used to drive the line.
Data is transmitted on the highway at DX on the
first eight positive transitions of CLKX following
the rising edge of FSX. Similarly, on the receive
side, data is received on the first eight falling
edges of CLKR. The frequency of CLKX and CLKR
is selected by the CLKSEL pin to be either 1.536,
1.544 or 2.048MHz. No other frequency of operation is allowed in the fixed data rate mode.
Variable Data Rate Mode
Variable data rate timing is selected by connecting DCLKR to the bit clock for the receive PCM
highway rather than to VBB. It employes master
clocks CLKX and CLKR, bit clocks DCLKR and
DCLKX and frame synchronization clocks FSR
and FSX.
Variable data rate timing allows for a flexible data
frequency. It provides the ability to vary the frequency of the bit clocks, from 64kHz to 4096MHz.
Master clocks inputs are still restricted to 1.536,
1.544, or 2.048MHz.
In this mode, DCLKR and DCLKX become the
data clocks for the receive and transmit PCM
highways. While FSX is high, PCM data from DX
is transmitted onto the highway on the next eight
consecutive positive transitions of DCLKX. Similarly, while FSR is high, each PCM bit from the
highway is received by D R on the next eight consecutive negative transitions of DCLKR.
On the transmit side, the PCM word will be repeated in all remaining timeslots in the 125µs
frame as long as DCLKX is pulsed and FSX is
held high. This feature allows the PCM word to be
transmitted to the PCM highway more than once
per frame, if desired, and is only available in the
variable data rate mode. Conversely, signaling is
only allowed in the fixed data rate mode since the
variable mode provides no means with which to
specify a signaling frame.
Precision Voltage References
No external components are required with the
combochip to provide the voltage reference function. Voltage references are generated on-chip
and are calibrated during the manufacturing process. The technique use the bandgap principle to
derive a temperature and bias stable reference
voltage. These references determine the gain and
dynamic range characteristics of the device.
Separate references are supplied to the transmit
and receive sections. Transmit and receive section are trimmed independently in the filter stages
to a final precision value. With this method the
combochip can achieve manufacturing tolerances
of typically ± 0.04dB in absolute gain for each half
channel, providing the user a significant margin
for error in other board components.
Conversion Laws
The M5913 is designed to operate in both µ-law
and A-law systems. The user can select either
conversion law according to the voltage present
on the SIGX/ASEL pin . In each case the coder
and decoder process a companded 8-bit PCM
word following CCITT recommandation G.711 for
µ-law and A-law conversion. If A-law operation is
desired, SIGX should be tied to VBB. Thus, signaling is not allowed during A-law operation. If µ =
255-law operation is selected, then SIGX is a TTL
level input which modifies the LSB on the PCM
output in signaling frames
TRANSMIT OPERATION
Transmit Filter
The input section provides gain adjustment in the
passband by means of an on-chip uncommitted
operational amplifier. This operational amplifier
has a common mode range of 2.17V, a maximum
DC offset of 25mV, a minimum voltage gain of
5000, and a unity gain bandwidth of typically
1MHz. Gain of up to 20dB can be set without degrading the performance of the filter. The load impedance to ground (GRDA) at the amplifier output
(GSX) must be greater than 10kΩ in parallel high
less than 50pF. The input signal on lead VFXI+
can be either AC or DC coupled. The input op
amp can also be used in the inverting mode or
differential amplifier mode (see figure 3).
A low pass anti-aliasing section is included onchip. This section typically provides 35dB attenuation at the sampling frequency. No external components are required to provide the necessary
anti-aliasing function for the switched capacitor
section of the transmit filter.
The passband section provides flatness and stopband attenuation which fulfills the AT&T D3/D4
channel bank transmission specification and
CCITT recommendation G.712.
The M5913 specifications meet or exceed digital
class 5 central office switching systems requirements. The transmit filter transfer characteristics
and specifications will be within the limits shown
the relative table.
A high pass section configuration was chosen to
reject low frequency noise from 50 and 60Hz
power lines, 17Hz European electric railroads,
ringing frequencies and their harmonics, and
other low frequency noise.
Even though there is high rejection at these frequencies, the sharpness of the band edge gives
low attenuation at 200Hz. This feature allows the
use of low-cost transformer hybrids without external components.
5/17
M5913
Figure 3: Transmit Filter Gain Adjustment.
an internal sample and hold capacitor. This sample is then transferred to the receive filter.
Receive Filter
The receive section of the filter provides passband flatness and stopband rejection which fulfills
both the AT&T D3/D4 specification and CCITT
recommendation G.712. The filter contains the required compensation for the (sin X)/X response of
such decoders. The receive filter characteristics
and specifications are shown in the relative table.
Encoding
The encoder internally samples the output of the
transmit filter and holds each sample on an internal sample and hold capacitor.
The encoder then performs an analog to digital
conversion on a switched capacitor array. Digital
data representing the sample is transmitted on
the first eight data clock bits of the next frame.
An on-chip autozero circuit corrects for DC-offset
on the input signal to the encoder. This autozero
circuit uses the sign bit averaging technique. In
this way, all DC offset is removed from the encoder input waveform.
RECEIVE OPERATION
Decoding
The PCM word at the DR lead is serially fetched
on the first eight data clock bits of the frame.
A D/A conversion is performed on the digital word
and the corresponding analog sample is held on
Figure 4: Gain Setting Configuration.
6/17
Receive Output Power Amplifiers
A balanced output amplifier is provided in order to
allow maximum flexibility in output configuration.
Either of the two outputs can be used single
ended (referenced to GRDA) to drive single
ended loads. Alternatively, the differential output
will drive a bridged load directly. The output stage
is capable of driving loads as low as 300 ohms
single ended to a level of 12dBm or 600 ohms differentially to a level of 15dBm.
The receive channel transmission level may be
adjusted between specified limits by manipulation
of the GSR input. GSR is internally connected to
an analog gain setting network. When GSR is
strapped to PWRO–, the receive level is minimized; when it is tied to PWRO+, the level is minimized. The output transmission level interpolates
between 0 and -12dB as GSR is interpolated
(with potentiometer) between PWRO- and
PWRO+. The use of the output gain set is illustrated in figure 4.
Transmission levels are specified relative to the
receive channel output under digital milliwatt conditions, that is, when the digital input at DR is the
eight-code sequence specified in CCITT recommendation G.711.
M5913
OUTPUT GAIN SET: DESIGN CONSIDERATIONS (refer to figure 4)
PWRO+ and PWRO– are low impedance complementary outputs. The voltages at the nodes are:
VO at PWRO+
VO at PWRO
VO = VO+ VO– (total differential response)
R1 and R2 are a gain setting resistor network with
the center tap connected to the GSR input. A
value greater than 10KΩ and less than 100KΩ for
R1 + R2 is recommended because:
a) The parallel combination of R1 + R2 and RL
sets the total loading.
b) The total capacitance at the GSR input and the
parallel combination of R1 and R2 define a
time constant which has to be minimized to
avoid inaccuracies.
If VA represents the output voltage without any
gain setting network connected, you can have:
VO = AVA
1 + (R1 / R2)
where A =
4 + (R1 / R2)
For design purposes, a useful form is R1/R2 as a
function of A.
4A – 1
R1 / R2 =
1 –A
(allowable values for A are those which make
R1/R2 positive)
Examples are:
If A = 1 (maximum output), then
R1/R2 = ∞ or V(GSR) = VO;
i.e., GSR is tied to PWRO+
If A = 1/2. then
R1/R2 = 2
If A = 1/4 (minimum output) then
R1/R2 = 0 or V(GSR ) = VO+;
i.e., GSR is tied to PWRO+
DC CHARACTERISTICS (Tamb = 0 to 70oC, VCC = +5V ± 5%, VBB = – 5V ± 5%, GRDA = 0V,unless otherwise specified) Typical values are for Tamb = 25oC and nominal power supply values.
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Unit
DIGITAL INTERFACE
IIL
Low Level Input Current
GRDD ≤ VIN ≤ VIL (note 1)
10
µA
IIH
High Level Input Current
VIH ≤ VIN ≤ VCC
10
µA
VIL
Input Low Voltage, Except CLKSEL
VIH
Input High Voltage, Except CLKSEL
VOL
Output Low Voltage
IOL = 3.2mA at DX, TSX and
SIGR
VOH
Output High Voltage
IOH = 9.6mA at DX
IOH = 1.2mA at SIGR
VILO
Input Low Voltage, CLKSEL (note 2)
VBB
VBB +
0.5
V
VIIO
Input Intermediate Voltage, CLKSEL
GRDD
-0.5
0.5
V
VIHO
Input High Voltage, CLKSEL
VCC 0.5
VCC
V
C OX
Digital Output Capacitance (note 3)
5
C IN
Digital Input Capacitance
5
10
pF
0.8
2.0
V
V
0.4
2.4
V
V
pF
Notes:
1. VIN is the voltage on any digital pin.
2. SIGX and DCLKR are TTL level inputs between GRDD and VCC; they are also pinstraps for mode selection when tied to VBB.
Under these conditions VILO is the input low voltage requirement.
3. Timing parameters are guaranteed based on a 100pF load capacitance.
Up to eight digital outputs may be connected to a common PCM highway without buffering, assuming a board capacitance of 60pF.
7/17
M5913
DC CHARACTERISTICS (continued)
Symbol
Parameter
Test Conditions
Min.
Typ.
Max
Unit
POWER DISSIPATION All measurements made at fDCLK = 2.048MHz, outputs unloaded
ICC1
VCC Operating Current
6
10
mA
IBB1
VBB Operating Current
6
9
mA
ICC0
VCC Power Down Current
PDN ≤ VIL ; after 10µs
40
300
µA
IBB0
VBB Power Down Current
PDN ≤ VIL ; after 10µs
40
300
µA
ICCS
VCC Standby Current
FSX, FSR ≤ VIL ; after 30ms
300
600
µA
IBBS
VBB Standby Current
FSX, FSR ≤ VIL ; after 30ms
40
300
µA
PD1
Operating Power Dissipation
60
100
mW
PD0
Power Down Dissipation
PDN ≤ VIL ; after 10µs
0.4
3
mW
PST
Standby Power Dissipation
FSX, FSR ≤ VIL ; after 30ms
1.7
5
mW
100
nA
ANALOG INTERFACE, RECEIVE FILTER DRIVER AMPLIFIER STAGE
IBX1
Input Leakage Current, VFXI+, VFXI-
R IXI
Input Resistance, VFXI+, VFXI-
-2.17V ≤ VIN ≤ 2.17V
10
VOSXI
Input Offset Voltage, VFXI+, VFXI-
CMRR
Common Mode Rejection, VFXI+, VFXI-
-2.17V ≤ VIN ≤ 2.17V
DC Open Loop Voltage Gain, GSX
RL = 10K
5000
RL ≥ 10kΩ
– 2.17
AVOL
fC
55
Open Loop Unity Gain Bandwidth, GSX
VOXI
Output Voltage Swing GSX
CLXI
Load Capacitance, GSX
RLXI
Minimum Load Resistance, GSX
MΩ
25
mV
dB
20.000
1
MHz
2.17
V
50
pF
10
kΩ
ANALOG INTERFACE, RECEIVE FILTER DRIVER AMPLIFIER STAGE
R ORA
Output Resistance, PWRO+, PWRO-
VOSRA
Single-ended Output DC Offset,
PWRO+, PWRO-
C LRA
Load Capacitance, PWRO+, PWRO-
Ω
1
Relative to GRDA
-150
75
150
mV
100
pF
AC CHARACTERISTICS - TRANSMISSION PARAMETERS
Unless otherwie noted, the analog input is a 0dBm0, 1020Hz sine wave1. Input amplifier is set for unity
gain, noninverting. The digital inputs is a PCM bit stream generated by passing a 0dBm0, 1020Hz sine
wave through an ideal encoder. Receive output is measured single ended, maximum gain configuration2.
All output levels are (sin X)/X corrected.
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Unit
± 0.04
+0.15
dBm0
+0.12
dB
+0.15
dBm0
+0.08
dB
GAIN AND DYNAMIC RANGE
Encoder Milliwatt Response
(transmit gain tolerance)
Tamb = 25°C, VBB = – 5V,
VCC = + 5V
-0.15
EmW Variation with Temperature and
Supplies
± 5% Supplies, 0 to 70°C
Relative to Nominal
Conditions
-0.12
Digital Milliwatt Response
(receive gain tolerance)
Tamb = 25°C ; VBB = – 5V,
VCC = + 5V
-0.15
DmW TS
DmW Variation with Temperature and
Supplies
± 5%, 0 to 70°C
-0.08
0TLP 1X
Zero Transmission Level Point
Transmit Channel (0dBm0) µ-law
Referenced to 600Ω
Referenced to 900Ω
+ 2.76
+ 1.00
dBm
dBm
0TLP 2X
Zero Transmission Level Point
Transmit Channel (0dBm0) A-law
Referenced to 600Ω
Referenced to 900Ω
+ 2.79
+ 1.03
dBm
dBm
0TLP1R
Zero Receive Level Point
Receive Channel (0dBm0) µ-law
Referenced to 600Ω
Referenced to 900Ω
+ 5.76
+ 4.00
dBm
dBm
0TLP2R
Zero Transmission Level Point
Transmit Channel (0dBm0)) A-law
Referenced to 600Ω
Referenced to 900Ω
+ 5.79
+ 4.03
dBm
dBm
EmW
EmWTS
DmW
8/17
± 0.04
M5913
AC CHARACTERISTICS (continued)
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Unit
GAIN TRACKING Reference Level = – 10dBm0
GT1X
Transmit Gain Tracking Error
Sinusoidal Input; µ-law
+ 3 to – 40dBm0
– 40 to – 50dBm0
– 50 to – 55dBm0
± 0.2
± 0.4
± 1.0
dB
dB
dB
GT2X
Transmit Gain Tracking Error
Sinusoidal Input; A-law
+ 3 to – 40dBm0
– 40 to – 50dBm0
– 50 to – 55dBm0
± 0.2
± 0.4
± 1.0
dB
dB
dB
GT1R
Receive Gain Tracking Error
Sinusoidal Input; µ-law
+ 3 to – 40dBm0
– 40 to – 50dBm0
– 50 to – 55dBm0
± 0.2
± 0.4
± 1.0
dB
dB
dB
GT2R
Receive Gain Tracking Error
Sinusoidal Input; A-law
+ 3 to – 40dBm0
– 40 to – 50dBm0
– 50 to – 55dBm0
± 0.2
± 0.4
± 1.0
dB
dB
dB
NOISE
N XC1
Transmit Noise, C-message Weighted
VFXI+ = GRDA, VFXI– = GSX
0
13
dBrnc0
N XC2
Transmit Noise, C-message
Weighted with Eighth Bit Signaling
VFXI+ = GRDA, VFXI– = GSX
6 th Frame Signaling
13
18
dBrnc0
NXP
Transmit Noise, Psophometrically
Weighted
VFXI+ = GRDA, VFXI– = GSX
(note 3)
– 80
dBrnc0
NRC1
Receive Noise, C-message Weighted:
Quiet Code
D R = 11111111 Measure at
PWRO+
1
9
dBrnc0
NRC2
Receive Noise, C-message Weighted:
Sign Bit Toggle
Input to D R is 0 code with
Sign Bit Toggle at 1KHz Rate
1
10
dBm0p
NRP
Receive Noise, Psophometrically
Weighted
D R = Lowest Positive Decode
Level
-90
– 81
dB0p
N SF
Single Frequency NOISE End to End
Measurement
CCITT G.712.4.2
– 50
dBm0
PSRR1
VCC Power Supply Rejection, Transmit
Channel
Idle Channel ; 200mV P-P
Signal on Supply ; 0 to
50kHz, Measure at DX
– 40
dB
PSRR2
VBB Power Supply Rejection, Transmit
Channel
Idle Channel ; 200mV P-P
Signal on Supply ; 0 to
50kHz, Measure at DX
– 40
dB
PSRR3
VCC Power Supply Rejection, Receive
Channel
Idle Channel ; 200mV P-P
Signal on Supply ; Measure
Narrow Band at PWRO+
Single Ended, 0 to 50kHz
– 40
dB
PSRR4
VBB Power Supply, Rejection Receive
Channel
Idle Channel ; 200mV P-P
Signal on Supply ; Measure
Narrow Band at PWRO+
Single Ended, 0 to 50kHz
– 40
dB
CTTR
Crosstalk, Transmit to Receive,
Single Ended Outputs
VFXI+ = 0dBm0, 1.02kHz,
D R = Lowest Positive Decode
Level, Measure at PWRO+
– 80
dB
CTRT
Crosstalk, Receive to Transmit,
Single Ended Outputs
D B = 0dBm0, 1.02kHz,
VFXI+ = GRDA, Measure at
DX
– 80
dB
Notes:
1. 0dBm0 is defined as the zero reference point of the channel under test (0TLP). This corresponds to an analog signal input of 1.064 Vrms
or an output of 1.503 Vrmst (µLaw) dual 1.068 Vrmst or a output 1.516 Vrmst (A-Law)
2. Unity gain input amplifier : GSX is connected to VFXI, Signal input VFXI+; Maximum gain output amplifier: GSR is connected to PWRO,
output to PWRO+.
3. Noise free: DX PCM Code stable at 01010101.
9/17
M5913
A.C. CHARACTERISTICS (continued)
Symbol
Parameter
DISTORTION
Transmit Signal to Distortion, µ-law
SD1X
Sinusoidal Input;
CCITT G.712-method 2
SD2X
Transmit Signal to Distortion, A-law
Sinusoidal Input,
CCITT G.712-method 2
SD1R
Transmit Signal to Distortion,
µ-law Sinusoidal Input ,
CCITT G.712-method 2
Receive Signal to Distortion, A-law
SD2R
Sinusoidal Input;
CCITT G.712-method 2
DP X1
Transmit Single Frequency Distortion
Products
Receive Single Frequency Distortion
DPR1
Products
Intermodulation Distortion,
IMD1
End to End Measurement
Intermodulation Distortion,
IMD2
End to End Measurement
SOS
Spurious Out of Band Signals,
End to End Measurement
SIS
Spurious in Band Signals,
End to End Measurement
Transmit Absolute Delay
DAX
DDX
Transmit Differential Envelope Delay
Relative to DAX
DAR
Receive Absolute Delay
D DR
Receive Differential Envelope Delay
Relative to DAR
10/17
Test Conditions
Max.
Unit
– 46
dB
dB
dB
dB
dB
dB
dB
dB
dB
dB
dB
dB
dB
– 46
dB
– 35
dB
CCITT G.712 (7.2)
– 49
dB
CCITT G.712 (6.1)
– 30
dBm0
CCITT G.712 (9)
– 40
dBm0
0 ≤ VFXI+ ≤ – 30dBm0
– 40dBm0
– 45dBm0
0 ≤ VFXI+ ≤ – 30dBm0
– 40dBm0
– 45dBm0
0 ≤ VFXI+ ≤ – 30dBm0
– 40dBm0
– 45dBm0
0 ≤ VFXI+ ≤ – 30dBm0
– 40dBm0
– 45dBm0
AT & T Adivisory # 64 (3.8)
0dBm0 Input Signal
AT & T Adivisory # 64 (3.8)
0dBm0 Input Signal
CCITT G.712 (7.1)
Fixed Data Rate CLKX =
2.048MHz,
0dBm0, 1.02kHz Signal at
VFXI+ Measure at D X
f = 500 – 600Hz
f = 600 – 1000Hz
f = 1000 – 2600Hz
f = 2600 – 2800Hz
Fixed data rate, CLKR =
2.048MHz;
Digital input is DMW codes.
Measure at PWRO+
f = 500 – 600Hz
f = 600 – 1000Hz
f = 1000 – 2600Hz
f = 2600 – 2800Hz
Min.
Typ.
36
30
25
36
30
25
36
30
25
36
30
25
300
µs
170
95
45
80
µs
µs
µs
µs
µs
190
10
10
85
110
µs
µs
µs
µs
M5913
A.C. CHARACTERISTICS (continued)
TRANSMIT CHANNEL TRANSFER CHARACTERISTICS
(Input amplifier is set for unity gain, noninverting; maximum gain output.)
Symbol
GRX
Parameter
Gain Relative to Gain at 1.02 kHz
16.67Hz
50Hz
60Hz
200Hz
300 to 3000Hz
3300Hz
3400Hz
4000Hz
4600Hz and Above
Test Conditions
0 dBm0 Signal Input at VFXI+
Min.
– 1.8
– 0.125
– 0.35
– 0.7
Typ.
Max.
Unit
– 30
– 25
– 23
– 0.125
+ 0.125
+ 0.03
– 0.10
– 14
– 32
dB
dB
dB
dB
dB
dB
dB
dB
dB
Figure 5: Transmit Filter
11/17
M5913
A.C. CHARACTERISTICS (continued)
RECEIVE CHANNEL TRANSFER CHARACTERISTICS
Symbol
GRR
Parameter
Gain Relative to Gainat 1.02kHz
below 200Hz
200Hz
300 to 3000Hz
3300Hz
3400Hz
4000Hz
4600Hz and Above
Figure 6: Receive Filter
12/17
Test Conditions
0dBm0 Signal Input at D R
Min.
– 0.5
– 0.125
– 0.35
– 0.7
Typ.
Max.
Unit
+ 0.125
+ 0.125
+ 0.125
+ 0.03
– 0.1
– 14
– 30
dB
dB
dB
dB
dB
dB
dB
M5913
AC CHARACTERISTICS - TIMING PARAMETERS
Symbol
Parameter
Test Conditions
CLOCK SECTION
Clock Period, CLKX, CLKR
fCLKX = fCLKR = 2.048MHz
tCY
tCLK
Clock Pulse Width
CLKX, CLKR
1
Data Clock Pulse Width
64kHz ≤ fDCLK ≤ 2.048MHz
tDCLK
Clock Duty Cycle
CLKX, CLKR
tCDC
Clock Rise and Fall Time
tr, tf
TRANSMIT SECTION, FIXED DATA RATE MODE2
tDZX
Data Enabled on TS Entry
0 < CLOAD < 100pF
Data Delay from CLKX
0 < CLOAD < 100pF
tDDX
Data Float on TS Exit
C LOAD = 0
tHZX
tSON
Timeslot X to Enable
0 < CLOAD < 100pF
Timeslot X to Disable
C LOAD = 0
tSOFF
tFSD
Frame Sync Delay
Signal Setup Time
tSS
Signal Setup Time
tSH
RECEIVE SECTION, FIXED DATA RATE MODE
Receive Data Setup
tDSR
tDHR
Receive Data Hold
Frame Sync Delay
tFSD
tSIGR
SIGR Update
TRANSMIT SECTION, FIXED DATA RATE MODE2
tTSDX
Timeslot Delay from DCLKX
Frame Sync Delay
tFSD
Data Delay from DCLKX
0 < CLOAD < 100pF
tDDX
tDON
Timeslot to D X Active
0 < CLOAD < 100pF
Timeslot to D X Inactive
0 < CLOAD < 100pF
tDOFF
fDX
Data Clock Frequency
Data Delay from FSX
tTSDX = 80ns
tDFSX
RECEIVE SECTION, FIXED DATA RATE MODE
Timeslot Delay from DCLKR
tTSDR
tFSD
Frame Sync Delay
Receive Data Setup Time
tDSR
Receive Data Hold Time
tDHR
Data Clock Frequency
tDR
tSER
Timeslot End Receive Time
64KB OPERATION, VARIABLE DATA RATE MODE
Transmit Frame Sync Minimum
FSX is TTL high for
tFSLX
Downtime
remainder of frame
Receive Frame Sync Miniumum
FSR is TTL high for
tFSLR
Downtime
remainder of frame
Data Clock Pulse Width
tDCLK
Min.
488
195
195
40
5
0
0
60
0
50
0
0
0
Typ.
50
Max.
Unit
60
30
ns
ns
ns
%
ns
145
145
190
145
190
120
ns
ns
ns
ns
ns
ns
ns
ns
10
60
0
0
120
2
ns
ns
ns
µs
-80
0
0
0
0
64
0
80
120
100
50
80
1
2048
140
ns
ns
ns
ns
ns
KHz
ns
-80
0
10
60
64
0
80
120
ns
ns
ns
ns
kHz
ns
20481
488
ns
1952
ns
10
µs
Notes:
1. Devices are available wich operate at data rates up to 4.096MHz; the minimum data clock pulse width for these devices is 110ns
2. Timing parameters tDZX, tHZX, and tSOFF are referenced to a high impedance state.
13/17
M5913
WAVEFORMS:
Fixed Data Rate Timing - Transmit Timing
NOTE: All timing parameters referenced to VIH and VIL except tDZX, tSOFF and tHZX which reference a high impedance state.
Receive Timing
NOTE: All timing parameters referenced to VIH and VIL
14/17
M5913
VARIABLE DATA RATE TIMING
AC Timing Input, Output Waveform
15/17
M5913
DIP20 PACKAGE MECHANICAL DATA
mm
DIM.
MIN.
a1
0.254
B
1.39
TYP.
MAX.
MIN.
TYP.
MAX.
0.010
1.65
0.055
0.065
b
0.45
0.018
b1
0.25
0.010
D
25.4
1.000
E
8.5
0.335
e
2.54
0.100
e3
22.86
0.900
F
7.1
0.280
I
3.93
0.155
L
Z
16/17
inch
3.3
0.130
1.34
0.053
M5913
Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsibility for the
consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No
license is granted by implication or otherwise under any patent or patent rights of SGS-THOMSON Microelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied.
SGS-THOMSON Microelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of SGS-THOMSON Microelectronics.
 1994 SGS-THOMSON Microelectronics - All Rights Reserved
SGS-THOMSON Microelectronics GROUP OF COMPANIES
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17/17