MOTOROLA MC145481SD

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by MC145481/D
SEMICONDUCTOR TECHNICAL DATA
Product Preview
The MC145481 is a general purpose per channel PCM Codec–Filter with pin
selectable Mu–Law or A–Law companding, and is offered in 20–pin SOG and
SSOP packages. This device performs the voice digitization and reconstruction
as well as the band limiting and smoothing required for PCM systems. This
device is designed to operate in both synchronous and asynchronous
applications and contains an on–chip precision reference voltage.
This device has an input operational amplifier whose output is the input to the
encoder section. The encoder section immediately low–pass filters the analog
signal with an active R–C filter to eliminate very high frequency noise from being
modulated down to the passband by the switched capacitor filter. From the
active R–C filter, the analog signal is converted to a differential signal. From this
point, all analog signal processing is done differentially. This allows processing
of an analog signal that is twice the amplitude allowed by a single–ended
design, which reduces the significance of noise to both the inverted and
non–inverted signal paths. Another advantage of this differential design is that
noise injected via the power supplies is a common–mode signal that is
cancelled when the inverted and non–inverted signals are recombined. This
dramatically improves the power supply rejection ratio.
After the differential converter, a differential switched capacitor filter band–
passes the analog signal from 200 Hz to 3400 Hz before the signal is digitized
by the differential compressing A/D converter.
The decoder accepts PCM data and expands it using a differential D/A
converter. The output of the D/A is low–pass filtered at 3400 Hz and sinX/X
compensated by a differential switched capacitor filter. The signal is then filtered
by an active R–C filter to eliminate the out–of–band energy of the switched
capacitor filter.
The MC145481 PCM Codec–Filter has a high impedance VAG reference pin
which allows for decoupling of the internal circuitry that generates the
mid–supply VAG reference voltage to the VSS power supply ground. This
reduces clock noise on the analog circuitry when external analog signals are
referenced to the power supply ground.
The MC145481 PCM Codec–Filter accepts a variety of clock formats,
including Short Frame Sync, Long Frame Sync, IDL, and GCI timing
environments. This device also maintains compatibility with Motorola’s family of
Telecommunication products, including the MC14LC5472 and MC145572
U–Interface Transceivers, MC145474/75 and MC145574 S/T–Interface Transc e i v e r s , M C 1 4 5 5 3 2 A D P C M Tr a n s c o d e r, M C 1 4 5 4 2 2 / 2 6 U D LT – 1 ,
MC145421/25 UDLT–2, and MC3419/MC33120 SLICs.
The MC145481 PCM Codec–Filter utilizes CMOS due to its reliable
low–power performance and proven capability for complex analog/digital VLSI
functions.
DW SUFFIX
SOG PACKAGE
CASE 751D
20
1
SD SUFFIX
SSOP
CASE 940C
20
1
ORDERING INFORMATION
MC145481DW
MC145481SD
SOG Package
SSOP
PIN ASSIGNMENT
VAG Ref
1
20
VAG
RO–
2
19
TI+
PI
3
18
TI–
PO–
4
17
TG
PO+
5
16
Mu/A
VDD
6
15
VSS
FSR
7
14
FST
DR
8
13
DT
BCLKR
9
12
BCLKT
10
11
MCLK
PDI
•
•
•
•
•
•
•
Single 2.7 to 5.25 V Power Supply
Typical Power Dissipation of 8 mW @ 3 V, Power–Down of 0.01 mW
Fully–Differential Analog Circuit Design for Lowest Noise
Transmit Band–Pass and Receive Low–Pass Filters On–Chip
Active R–C Pre–Filtering and Post–Filtering
Mu–Law and A–Law Companding by Pin Selection
On–Chip Precision Reference Voltage of 0.886 V for a – 5 dBm TLP
@ 600 Ω
• Push–Pull 300 Ω Power Drivers with External Gain Adjust
This document contains information on a product under development. Motorola reserves the right to change or discontinue this product without notice.
REV 1
7/96

Motorola, Inc. 1996
MOTOROLA
MC145481
1
RECEIVE
SHIFT
REGISTER
RO –
DR
DAC
FREQ
PI
FSR
–
+
PO –
BCLKR
SHARED
DAC
Mu/A
–1
PO +
VDD
SEQUENCE
AND
CONTROL
VDD
VSS
R*
MCLK
0.886 V
REF
VAG Ref
1
VAG
PDI
BCLKT
R*
FST
VSS
TG
TI –
TI +
–
+
ADC
FREQ
TRANSMIT
SHIFT
REGISTER
DT
Figure 1. MC145481 3 V PCM Codec–Filter Block Diagram
DEVICE DESCRIPTION
A PCM Codec–Filter is used for digitizing and reconstructing the human voice. These devices are used primarily for
the telephone network to facilitate voice switching and transmission. Once the voice is digitized, it may be switched by
digital switching methods or transmitted long distance (T1,
microwave, satellites, etc.) without degradation. The name
codec is an acronym from ‘‘COder’’ for the analog–to–digital
converter (ADC) used to digitize voice, and ‘‘DECoder’’ for
the digital–to–analog converter (DAC) used for reconstructing voice. A codec is a single device that does both the ADC
and DAC conversions.
To digitize intelligible voice requires a signal–to–distortion
ratio of about 30 dB over a dynamic range of about 40 dB.
This may be accomplished with a linear 13–bit ADC and
DAC, but will far exceed the required signal–to–distortion
ratio at larger amplitudes than 40 dB below the peak amplitude. This excess performance is at the expense of data per
sample. Two methods of data reduction are implemented by
compressing the 13–bit linear scheme to companded
pseudo–logarithmic 8–bit schemes. The two companding
schemes are: Mu–255 Law, primarily in North America and
Japan; and A–Law, primarily used in Europe. These companding schemes are accepted world wide. These companding schemes follow a segmented or ‘‘piecewise–linear’’ curve
formatted as sign bit, three chord bits, and four step bits. For
a given chord, all sixteen of the steps have the same voltage
weighting. As the voltage of the analog input increases, the
four step bits increment and carry to the three chord bits
MC145481
2
which increment. When the chord bits increment, the step
bits double their voltage weighting. This results in an effective resolution of six bits (sign + chord + four step bits) across
a 42 dB dynamic range (seven chords above 0, by 6 dB per
chord).
In a sampling environment, Nyquist theory says that to
properly sample a continuous signal, it must be sampled at a
frequency higher than twice the signal’s highest frequency
component. Voice contains spectral energy above 3 kHz, but
its absence is not detrimental to intelligibility. To reduce the
digital data rate, which is proportional to the sampling rate, a
sample rate of 8 kHz was adopted, consistent with a bandwidth of 3 kHz. This sampling requires a low–pass filter to
limit the high frequency energy above 3 kHz from distorting
the in–band signal. The telephone line is also subject to
50/60 Hz power line coupling, which must be attenuated
from the signal by a high–pass filter before the analog–to–
digital converter.
The digital–to–analog conversion process reconstructs a
staircase version of the desired in–band signal, which has
spectral images of the in–band signal modulated about the
sample frequency and its harmonics. These spectral images
are called aliasing components, which need to be attenuated
to obtain the desired signal. The low–pass filter used to attenuate these aliasing components is typically called a reconstruction or smoothing filter.
The MC145481 PCM Codec–Filter has the codec, both
presampling and reconstruction filters, and a precision voltage reference on–chip.
MOTOROLA
PIN DESCRIPTIONS
POWER SUPPLY
VDD
Positive Power Supply (Pin 6)
This is the most positive power supply and is typically connected to + 3 V. This pin should be decoupled to VSS with a
0.1 µF ceramic capacitor.
VSS
Negative Power Supply (Pin 15)
This is the most negative power supply and is typically
connected to 0 V.
VAG
Analog Ground Output (Pin 20)
This output pin provides a mid–supply analog ground. This
pin should be decoupled to VSS with a 0.01 µF ceramic capacitor. All analog signal processing within this device is referenced to this pin. If the audio signals to be processed are
referenced to V SS, then special precautions must be utilized
to avoid noise between V SS and the VAG pin. Refer to the applications information in this document for more information.
The VAG pin becomes high impedance when this device is in
the powered–down mode.
VAG Ref
Analog Ground Reference Bypass (Pin 1)
This pin is used to capacitively bypass the on–chip circuitry that generates the mid–supply voltage for the VAG output
pin. This pin should be bypassed to VSS with a 0.1 µF ceramic capacitor using short, low inductance traces. The VAG Ref
pin is only used for generating the reference voltage for the
VAG pin. Nothing is to be connected to this pin in addition to
the bypass capacitor. All analog signal processing within this
device is referenced to the VAG pin. If the audio signals to be
processed are referenced to VSS, then special precautions
must be utilized to avoid noise between VSS and the VAG pin.
Refer to the applications information in this document for
more information. When this device is in the powered–down
mode, the VAG Ref pin is pulled to the VDD power supply with
a non–linear, high–impedance circuit.
CONTROL
Mu/A
Mu/A Law Select (Pin 16)
This pin controls the compression for the encoder and the
expansion for the decoder. Mu–Law companding is selected
when this pin is connected to VDD and A–Law companding is
selected when this pin is connected to VSS.
PDI
Power–Down Input (Pin 10)
This pin puts the device into a low power dissipation mode
when a logic 0 is applied. When this device is powered down,
all of the clocks are gated off and all bias currents are turned
off, which causes RO–, PO–, PO+, TG, VAG, and DT to be-
MOTOROLA
come high impedance and the VAG Ref pin is pulled to the
VDD power supply with a non–linear, high–impedance circuit.
The device will operate normally when a logic 1 is applied to
this pin. The device goes through a power–up sequence
when this pin is taken to a logic 1 state, which prevents the
DT PCM output from going low impedance for at least two
FST cycles. The VAG and VAG Ref circuits and the signal processing filters must settle out before the DT PCM output or
the RO– receive analog output will represent a valid analog
signal.
ANALOG INTERFACE
TI+
Transmit Analog Input (Non–Inverting) (Pin 19)
This is the non–inverting input of the transmit input gain
setting operational amplifier. This pin accommodates a differential to single–ended circuit for the input gain setting op
amp. This allows input signals that are referenced to the V SS
pin to be level shifted to the VAG pin with minimum noise.
This pin may be connected to the VAG pin for an inverting
amplifier configuration if the input signal is already referenced to the VAG pin. The common mode range of the TI+
and TI– pins is from 1.2 V, to V DD minus 1.2 V. This is an FET
gate input.
The TI+ pin also serves as a digital input control for the
transmit input multiplexer. Connecting the TI+ pin to VDD will
place this amplifier’s output (TG) into a high–impedance
state, and selects the TG pin to serve as a high–impedance
input to the transmit filter. Connecting the TI+ pin to VSS will
also place this amplifier’s output (TG) into a high–impedance
state, and selects the TI– pin to serve as a high–impedance
input to the transmit filter.
TI–
Transmit Analog Input (Inverting) (Pin 18)
This is the inverting input of the transmit gain setting operational amplifier. Gain setting resistors are usually connected from this pin to TG and from this pin to the analog
signal source. The common mode range of the TI+ and TI–
pins is from 1.2 V to VDD – 1.2 V. This is an FET gate input.
The TI– pin also serves as one of the transmit input multiplexer pins when the TI+ pin is connected to VSS. When TI+
is connected to VDD, this pin is ignored. See the pin descriptions for the TI+ and the TG pins for more information.
TG
Transmit Gain (Pin 17)
This is the output of the transmit gain setting operational
amplifier and the input to the transmit band–pass filter. This
op amp is capable of driving a 2 kΩ load. Connecting the TI+
pin to VDD will place the TG pin into a high–impedance state,
and selects the TG pin to serve as a high–impedance input to
the transmit filter. All signals at this pin are referenced to the
VAG pin. When TI+ is connected to VSS, this pin is ignored.
See the pin descriptions for the TI+ and TI– pins for more information. This pin is high impedance when the device is in
the powered–down mode.
MC145481
3
RO–
Receive Analog Output (Inverting) (Pin 2)
This is the inverting output of the receive smoothing filter
from the digital–to–analog converter. This output is capable
of driving a 2 kΩ load to 0.886 V peak referenced to the VAG
pin. If the device is operated half–channel with the FST pin
clocking and FSR pin held low, the receive filter input will be
conencted to the VAG voltage. This minimizes transients at
the RO– pin when full–channel operation is resumed by
clocking the FSR pin. This pin is high impedance when the
device is in the powered–down mode.
PI
Power Amplifier Input (Pin 3)
This is the inverting input to the PO– amplifier. The non–
inverting input to the PO– amplifier is internally tied to the
VAG pin. The PI and PO– pins are used with external resistors in an inverting op amp gain circuit to set the gain of the
PO+ and PO– push–pull power amplifier outputs. Connecting PI to VDD will power down the power driver amplifiers and
the PO+ and PO– outputs will be high impedance.
PO–
Power Amplifier Output (Inverting) (Pin 4)
This is the inverting power amplifier output, which is used
to provide a feedback signal to the PI pin to set the gain of
the push–pull power amplifier outputs. This pin is capable of
driving a 300 Ω load to PO+. The PO+ and PO– outputs are
differential (push–pull) and capable of driving a 300 Ω load to
1.772 V peak, which is 3.544 V peak–to–peak. The bias voltage and signal reference of this output is the VAG pin. The
VAG pin cannot source or sink as much current as this pin,
and therefore low impedance loads must be between PO+
and PO–. The PO+ and PO– differential drivers are also capable of driving a 100 Ω resistive load or a 100 nF Piezoelectric transducer in series with a 20 Ω resister with a small
increase in distortion. These drivers may be used to drive resistive loads of ≥ 32 Ω when the gain of PO– is set to 1/4 or
less. Connecting PI to VDD will power down the power driver
amplifiers and the PO+ and PO– outputs will be high impedance. This pin is also high impedance when the device is
powered down by the PDI pin.
PO+
Power Amplifier Output (Non–Inverting) (Pin 5)
This is the non–inverting power amplifier output, which is
an inverted version of the signal at PO–. This pin is capable
of driving a 300 Ω load to PO–. Connecting PI to VDD will
power down the power driver amplifiers and the PO+ and
PO– outputs will be high impedance. This pin is also high impedance when the device is powered down by the PDI pin.
See PI and PO– for more information.
DIGITAL INTERFACE
MCLK
Master Clock (Pin 11)
This is the master clock input pin. The clock signal applied
to this pin is used to generate the internal 256 kHz clock and
sequencing signals for the switched–capacitor filters, ADC,
and DAC. The internal prescaler logic compares the clock on
MC145481
4
this pin to the clock at FST (8 kHz) and will automatically
accept 256, 512, 1536, 1544, 2048, 2560, or 4096 kHz. For
MCLK frequencies of 256 and 512 kHz, MCLK must be synchronous and approximately rising edge aligned to FST. For
optimum performance at frequencies of 1.536 MHz and
higher, MCLK should be synchronous and approximately rising edge aligned to the rising edge of FST. In many applications, MCLK may be tied to the BCLKT pin.
FST
Frame Sync, Transmit (Pin 14)
This pin accepts an 8 kHz clock that synchronizes the output of the serial PCM data at the DT pin. This input is compatible with various standards including IDL, Long Frame
Sync, Short Frame Sync, and GCI formats. If both FST and
FSR are held low for several 8 kHz frames, the device will
power down.
BCLKT
Bit Clock, Transmit (Pin 12)
This pin controls the transfer rate of transmit PCM data. In
the IDL and GCI modes it also controls the transfer rate of
the receive PCM data. This pin can accept any bit clock frequency from 64 to 4096 kHz for Long Frame Sync and Short
Frame Sync timing. This pin can accept clock frequencies
from 256 kHz to 4.096 MHz in IDL mode, and from 512 kHz
to 6.176 MHz for GCI timing mode.
DT
Data, Transmit (Pin 13)
This pin is controlled by FST and BCLKT and is high impedance except when outputting PCM data. When operating
in the IDL or GCI mode, data is output in either the B1 or B2
channel as selected by FSR. This pin is high impedance
when the device is in the powered down mode.
FSR
Frame Sync, Receive (Pin 7)
When used in the Long Frame Sync or Short Frame Sync
mode, this pin accepts an 8 kHz clock, which synchronizes
the input of the serial PCM data at the DR pin. FSR can be
asynchronous to FST in the Long Frame Sync or Short
Frame Sync modes. When an ISDN mode (IDL or GCI) has
been selected with BCLKR, this pin selects either B1 (logic 0)
or B2 (logic 1) as the active data channel.
BCLKR
Bit Clock, Receive (Pin 9)
When used in the Long Frame Sync or Short Frame Sync
mode, this pin accepts any bit clock frequency from 64 to
4096 kHz. When this pin is held at a logic 1, FST, BCLKT, DT,
and DR become IDL Interface compatible. When this pin is
held at a logic 0, FST, BCLKT, DT, and DR become GCI Interface compatible.
DR
Data, Receive (Pin 8)
This pin is the PCM data input, and when in a Long Frame
Sync or Short Frame Sync mode is controlled by FSR and
BCLKR. When in the IDL or GCI mode, this data transfer is
controlled by FST and BCLKT. FSR and BCLKR select the
B channel and ISDN mode, respectively.
MOTOROLA
FUNCTIONAL DESCRIPTION
ANALOG INTERFACE AND SIGNAL PATH
The transmit portion of this device includes a low–noise,
three–terminal op amp capable of driving a 2 kΩ load. This
op amp has inputs of TI+ (Pin 19) and TI– (Pin 18) and its
output is TG (Pin 17). This op amp is intended to be configured in an inverting gain circuit. The analog signal may be
applied directly to the TG pin if this transmit op amp is independently powered down by connecting the TI+ input to the
VDD power supply. The TG pin becomes high impedance
when the transmit op amp is powered down. The TG pin is
internally connected to a 3–pole anti–aliasing pre–filter. This
pre–filter incorporates a 2–pole Butterworth active low–pass
filter, followed by a single passive pole. This pre–filter is followed by a single–ended to differential converter that is
clocked at 512 kHz. All subsequent analog processing utilizes fully–differential circuitry. The next section is a fully–differential, 5–pole switched–capacitor low–pass filter with a
3.4 kHz frequency cutoff. After this filter is a 3–pole
switched–capacitor high–pass filter having a cutoff frequency of about 200 Hz. This high–pass stage has a transmission zero at dc that eliminates any dc coming from the
analog input or from accumulated op amp offsets in the preceding filter stages. The last stage of the high–pass filter is
an autozeroed sample and hold amplifier.
One bandgap voltage reference generator and digital–to–
analog converter (DAC) are shared by the transmit and receive sections. The autozeroed, switched–capacitor
bandgap reference generates precise positive and negative
reference voltages that are virtually independent of temperature and power supply voltage. A binary–weighted capacitor
array (CDAC) forms the chords of the companding structure,
while a resistor string (RDAC) implements the linear steps
within each chord. The encode process uses the DAC, the
voltage reference, and a frame–by–frame autozeroed
comparator to implement a successive–approximation conversion algorithm. All of the analog circuitry involved in the
data conversion (the voltage reference, RDAC, CDAC, and
comparator) are implemented with a differential architecture.
The receive section includes the DAC described above, a
sample and hold amplifier, a 5–pole, 3400 Hz switched capacitor low–pass filter with sinX/X correction, and a 2–pole
active smoothing filter to reduce the spectral components of
the switched capacitor filter. The output of the smoothing filter is buffered by an amplifier, which is output at the RO– pin.
This output is capable of driving a 2 kΩ load to the VAG pin.
The MC145481 also has a pair of power amplifiers that are
connected in a push–pull configuration. The PI pin is the inverting input to the PO– power amplifier. The non–inverting
input is internally tied to the VAG pin. This allows this amplifier
to be used in an inverting gain circuit with two external resis-
MOTOROLA
tors. The PO+ amplifier has a gain of minus one, and is internally connected to the PO– output. This complete power
amplifier circuit is a differential (push–pull) amplifier with adjustable gain that is capable of driving a 300 Ω load to
+7 dBm. The power amplifier may be powered down independently of the rest of the chip by connecting the PI pin to
VDD.
POWER–DOWN
There are two methods of putting this device into a low
power consumption mode, which makes the device nonfunctional and consumes virtually no power. PDI is the power–
down input pin which, when taken low, powers down the
device. Another way to power the device down is to hold both
the FST and FSR pins low while the BCLKT and MCLK pins
are clocked. When the chip is powered down, the VAG, TG,
RO–, PO+, PO–, and DT outputs are high impedance and
the VAG Ref pin is pulled to the VDD power supply with a non–
linear, high–impedance circuit. To return the chip to the power–up state, PDI must be high and the FST frame sync pulse
must be present while the BCLKT and MCLK pins are
clocked. The DT output will remain in a high–impedance
state for at least two 8 kHz FST pulses after power–up.
MASTER CLOCK
Since this codec–filter design has a single DAC architecture, the MCLK pin is used as the master clock for all analog
signal processing including analog–to–digital conversion,
digital–to–analog conversion, and for transmit and receive filtering functions of this device. The clock frequency applied to
the MCLK pin may be 256 kHz, 512 kHz, 1.536 MHz,
1.544 MHz, 2.048 MHz, 2.56 MHz, or 4.096 MHz. This device has a prescaler that automatically determines the proper
divide ratio to use for the MCLK input, which achieves the required 256 kHz internal sequencing clock. The clocking requirements of the MCLK input are independent of the PCM
data transfer mode (i.e., Long Frame Sync, Short Frame
Sync, IDL mode, or GCI mode).
DIGITAL I/O
The MC145481 is pin selectable for Mu–Law or A–Law.
Table 1 shows the 8–bit data word format for positive and
negative zero and full scale for both companding schemes.
Table 2 shows the series of eight PCM words for both Mu–
Law and A–Law that correspond to a digital milliwatt. The
digital mW is the 1 kHz calibration signal reconstructed by
the DAC that defines the absolute gain or 0 dBm0 Transmission Level Point (TLP) of the DAC. The timing for the PCM
data transfer is independent of the companding scheme selected. Refer to Figure 2 for a summary and comparison of
the four PCM data interface modes of this device.
MC145481
5
Table 1. PCM Codes for Zero and Full Scale
Mu–Law
L
l
Level
A–Law
Sign Bit
Chord Bits
Step Bits
Sign Bit
Chord Bits
Step Bits
+ Full Scale
1
000
0000
1
010
1010
+ Zero
1
111
1111
1
101
0101
– Zero
0
111
1111
0
101
0101
– Full Scale
0
000
0000
0
010
1010
Table 2. PCM Codes for Digital mW
Mu–Law
Ph
Phase
A–Law
Sign Bit
Chord Bits
Step Bits
Sign Bit
Chord Bits
Step Bits
π/8
0
001
1110
0
011
0100
3π/8
0
000
1011
0
010
0001
5π/8
0
000
1011
0
010
0001
7π/8
0
001
1110
0
011
0100
9π/8
1
001
1110
1
011
0100
11π/8
1
000
1011
1
010
0001
13π/8
1
000
1011
1
010
0001
15π/8
1
001
1110
1
011
0100
MC145481
6
MOTOROLA
FST (FSR)
BCLKT (BCLKR)
DT
DR
DON’T CARE
1
2
3
4
5
6
7
1
2
3
4
5
6
7
8
8
DON’T CARE
Figure 2a. Long Frame Sync (Transmit and Receive Have Individual Clocking)
FST (FSR)
BCLKT (BCLKR)
DT
DR
DON’T CARE
1
2
3
4
5
6
7
1
2
3
4
5
6
7
8
8
DON’T CARE
Figure 2b. Short Frame Sync (Transmit and Receive Have Individual Clocking)
IDL SYNC (FST)
IDL CLOCK (BCLKT)
IDL TX (DT)
IDL RX (DR)
DON’T CARE
1
2
3
4
5
6
7
1
2
3
4
5
6
7
8
8
DON’T
CARE
B1–CHANNEL (FSR = 0)
1
2
3
4
5
6
7
1
2
3
4
5
6
7
8
8
DON’T
CARE
B2–CHANNEL (FSR = 1)
Figure 2c. IDL Interface — BCLKR = 1 (Transmit and Receive Have Common Clocking)
FSC (FST)
DCL (BCLKT)
Dout (DT)
Din (DR)
DON’T
CARE
1
2
3
4
5
6
7
1
2
3
4
5
6
7
B1–CHANNEL (FSR = 0)
8
8
1
2
3
4
5
6
7
8
1
2
3
4
5
6
7
8
DON’T CARE
B2–CHANNEL (FSR = 1)
Figure 2d. GCI Interface — BCLKR = 0 (Transmit and Receive Have Common Clocking)
Figure 2. Digital Timing Modes for the PCM Data Interface
MOTOROLA
MC145481
7
Long Frame Sync
Long Frame Sync is the industry name for one type of
clocking format that controls the transfer of the PCM data
words. (Refer to Figure 2a.) The ‘‘Frame Sync’’ or ‘‘Enable’’ is
used for two specific synchronizing functions. The first is to
synchronize the PCM data word transfer, and the second is
to control the internal analog–to–digital and digital–to–analog
conversions. The term ‘‘Sync’’ refers to the function of synchronizing the PCM data word onto or off of the multiplexed
serial PCM data bus, which is also known as a PCM highway. The term ‘‘Long’’ comes from the duration of the frame
sync measured in PCM data clock cycles. Long Frame Sync
timing occurs when the frame sync is used directly as the
PCM data output driver enable. This results in the PCM output going low impedance with the rising edge of the transmit
frame sync, and remaining low impedance for the duration of
the transmit frame sync.
The implementation of Long Frame Sync has maintained
compatibility and been optimized for external clocking simplicity. This optimization includes the PCM data output going
low impedance with the logical AND of the transmit frame
sync (FST) with the transmit data bit clock (BCLKT). The optimization also includes the PCM data output (DT) remaining
low impedance until the middle of the LSB (seven and a half
PCM data clock cycles) or until the FST pin is taken low,
whichever occurs last. This requires the frame sync to be
approximately rising edge aligned with the initiation of the
PCM data word transfer, but the frame sync does not have a
precise timing requirement for the end of the PCM data word
transfer. The device recognizes Long Frame Sync clocking
when the frame sync is held high for two consecutive falling
edges of the transmit data clock. The transmit logic decides
on each frame sync whether it should interpret the next
frame sync pulse as a Long or a Short Frame Sync. This decision is used for receive circuitry also. The device is designed to prevent PCM bus contention by not allowing the
PCM data output to go low impedance for at least two frame
sync cycles after power is applied or when coming out of the
powered down mode.
The receive side of the device is designed to accept the
same frame sync and data clock as the transmit side and to
be able to latch its own transmit PCM data word. Thus the
PCM digital switch needs to be able to generate only one
type of frame sync for use by both transmit and receive sections of the device.
The logical AND of the receive frame sync with the receive
data clock tells the device to start latching the 8–bit serial
word into the receive data input on the falling edges of the
receive data clock. The internal receive logic counts the receive data clock cycles and transfers the PCM data word to
the digital–to–analog converter sequencer on the ninth data
clock rising edge.
This device is compatible with four digital interface modes.
To ensure that this device does not reprogram itself for a different timing mode, the BCLKR pin must change logic state
no less than every 125 µs. The minimum PCM data bit clock
frequency of 64 kHz satisfies this requirement.
Short Frame Sync
Short Frame Sync is the industry name for the type of
clocking format that controls the transfer of the PCM data
words (refer to Figure 2b). The ‘‘Frame Sync’’ or ‘‘Enable’’ is
MC145481
8
used for two specific synchronizing functions. The first is to
synchronize the PCM data word transfer, and the second is
to control the internal analog–to–digital and digital–to–analog
conversions. The term ‘‘Sync’’ refers to the function of synchronizing the PCM data word onto or off of the multiplexed
serial PCM data bus, which is also known as a PCM highway. The term ‘‘Short’’ comes from the duration of the frame
sync measured in PCM data clock cycles. Short Frame Sync
timing occurs when the frame sync is used as a ‘‘pre–synchronization’’ pulse that is used to tell the internal logic to
clock out the PCM data word under complete control of the
data clock. The Short Frame Sync is held high for one falling
data clock edge. The device outputs the PCM data word beginning with the following rising edge of the data clock. This
results in the PCM output going low impedance with the rising edge of the transmit data clock, and remaining low impedance until the middle of the LSB (seven and a half PCM
data clock cycles).
The device recognizes Short Frame Sync clocking when
the frame sync is held high for one and only one falling edge
of the transmit data clock. The transmit logic decides on each
frame sync whether it should interpret the next frame sync
pulse as a Long or a Short Frame Sync. This decision is used
for receive circuitry also. The device is designed to prevent
PCM bus contention by not allowing the PCM data output to
go low impedance for at least two frame sync cycles after
power is applied or when coming out of the powered down
mode.
The receive side of the device is designed to accept the
same frame sync and data clock as the transmit side and to
be able to latch its own transmit PCM data word. Thus the
PCM digital switch needs to be able to generate only one
type of frame sync for use by both transmit and receive sections of the device.
The falling edge of the receive data clock latching a high
logic level at the receive frame sync input tells the device to
start latching the 8–bit serial word into the receive data input
on the following eight falling edges of the receive data clock.
The internal receive logic counts the receive data clock
cycles and transfers the PCM data word to the digital–to–
analog converter sequencer on the rising data clock edge after the LSB has been latched into the device.
This device is compatible with four digital interface modes.
To ensure that this device does not reprogram itself for a different timing mode, the BCLKR pin must change logic state
no less than every 125 µs. The minimum PCM data bit clock
frequency of 64 kHz satisfies this requirement.
Interchip Digital Link (IDL)
The Interchip Digital Link (IDL) Interface is one of two
standard synchronous 2B+D ISDN timing interface modes
with which this device is compatible. In the IDL mode, the device can communicate in either of the two 64 kbps B channels (refer to Figure 2c for sample timing). The IDL mode is
selected when the BCLKR pin is held high for two or more
FST (IDL SYNC) rising edges. The digital pins that control
the transmit and receive PCM word transfers are reprogrammed to accommodate this mode. The pins affected are
FST, FSR, BCLKT, DT, and DR. The IDL Interface consists of
four pins: IDL SYNC (FST), IDL CLK (BCLKT), IDL TX (DT),
and IDL RX (DR). The IDL interface mode provides access to
both the transmit and receive PCM data words with common
control clocks of IDL Sync and IDL Clock. In this mode, the
MOTOROLA
FSR pin controls whether the B1 channel or the B2 channel
is used for both transmit and receive PCM data word transfers. When the FSR pin is low, the transmit and receive PCM
words are transferred in the B1 channel, and for FSR high
the B2 channel is selected. The start of the B2 channel is ten
IDL CLK cycles after the start of the B1 channel.
The IDL SYNC (FST, Pin 14) is the input for the IDL frame
synchronization signal. The signal at this pin is nominally
high for one cycle of the IDL Clock signal and is rising edge
aligned with the IDL Clock signal. (Refer to Figure 4 and the
IDL Timing specifications for more details.) This event identifies the beginning of the IDL frame. The frequency of the IDL
Sync signal is 8 kHz. The rising edge of the IDL SYNC (FST)
should be aligned approximately with the rising edge of
MCLK. MCLK must be one of the clock frequencies specified
in the Digital Switching Characteristics table, and is typically
tied to IDL CLK (BCLKT).
The IDL CLK (BCLKT, Pin 12) is the input for the PCM
data clock. All IDL PCM transfers and data control sequencing are controlled by this clock following the IDL SYNC. This
pin accepts an IDL data clock frequency of 256 kHz to 4.096
MHz.
The IDL TX (DT, Pin 13) is the output for the transmit PCM
data word. Data bits are output for the B1 channel on sequential rising edges of the IDL CLK signal beginning after
the IDL SYNC pulse. If the B2 channel is selected, then the
PCM word transfer starts on the eleventh IDL CLK rising
edge after the IDL SYNC pulse. The IDL TX pin will remain
low impedance for the duration of the PCM word until the
LSB after the falling edge of IDL CLK. The IDL TX pin will remain in a high impedance state when not outputting PCM
data or when a valid IDL Sync signal is missing.
The IDL RX (DR, Pin 8) is the input for the receive PCM
data word. Data bits are input for the B1 channel on sequential falling edges of the IDL CLK signal beginning after the
IDL SYNC pulse. If the B2 channel is selected, then the PCM
word is latched in starting on the eleventh IDL CLK falling
edge after the IDL SYNC pulse.
General Circuit Interface (GCI)
The General Circuit Interface (GCI) is the second of two
standard synchronous 2B+D ISDN timing interface modes
with which this device is compatible. In the GCI mode, the
device can communicate in either of the two 64 kbps B–
channels. (Refer to Figure 2d for sample timing.) The GCI
mode is selected when the BCLKR pin is held low for two or
more FST (FSC) rising edges. The digital pins that control
the transmit and receive PCM word transfers are reprogrammed to accommodate this mode. The pins affected are
FST, FSR, BCLKT, DT, and DR. The GCI Interface consists
of four pins: FSC (FST), DCL (BCLKT), Dout (DT), and Din
(DR). The GCI interface mode provides access to both the
transmit and receive PCM data words with common control
clocks of FSC (frame synchronization clock) and DCL (data
clock). In this mode, the FSR pin controls whether the B1
channel or the B2 channel is used for both transmit and receive PCM data word transfers. When the FSR pin is low, the
transmit and receive PCM words are transferred in the B1
channel, and for FSR high the B2 channel is selected. The
start of the B2 channel is 16 DCL cycles after the start of the
B1 channel.
MOTOROLA
The FSC (FST, Pin 14) is the input for the GCI frame synchronization signal. The signal at this pin is nominally rising
edge aligned with the DCL clock signal. (Refer to Figure 6
and the GCI Timing specifications for more details.) This
event identifies the beginning of the GCI frame. The frequency of the FSC synchronization signal is 8 kHz. The rising
edge of the FSC (FST) should be aligned approximately with
the rising edge of MCLK. MCLK must be one of the clock frequencies specified in the Digital Switching Characteristics
table, and is typically tied to DCL (BCLKT).
The DCL (BCLKT, Pin 12) is the input for the clock that
controls the PCM data transfers. The clock applied at the
DCL input is twice the actual PCM data rate. The GCI frame
begins with the logical AND of the FSC with the DCL. This
event initiates the PCM data word transfers for both transmit
and receive. This pin accepts a GCI data clock frequency of
512 kHz to 6.176 MHz for PCM data rates of 256 kHz to
3.088 MHz.
The GCI Dout (DT, Pin 13) is the output for the transmit
PCM data word. Data bits are output for the B1 channel on
alternate rising edges of the DCL clock signal, beginning with
the FSC pulse. If the B2 channel is selected, then the PCM
word transfer starts on the seventeenth DCL rising edge after
the FSC rising edge. The Dout pin will remain low impedance
for 15–1/2 DCL clock cycles. The Dout pin becomes high
impedance after the second falling edge of the DCL clock
during the LSB of the PCM word. The Dout pin will remain in
a high–impedance state when not outputting PCM data or
when a valid FSC signal is missing.
The Din (DR, Pin 8) is the input for the receive PCM data
word. Data bits are latched in for the B1 channel on alternate
rising edges of the DCL clock signal, beginning with the second DCL clock after the rising edge of the FSC pulse. If the
B2 channel is selected then the PCM word is latched in starting on the eighteenth DCL rising edge after the FSC rising
edge.
PRINTED CIRCUIT BOARD LAYOUT
CONSIDERATIONS
The MC145481 is manufactured using high–speed CMOS
VLSI technology to implement the complex analog signal
processing functions of a PCM Codec–Filter. The fully–differential analog circuit design techniques used for this device
result in superior performance for the switched capacitor filters, the analog–to–digital converter (ADC) and the digital–
to–analog converter (DAC). Special attention was given to
the design of this device to reduce the sensitivities of noise,
including power supply rejection and susceptibility to radio
frequency noise. This special attention to design includes a
fifth order low–pass filter, followed by a third order high–pass
filter whose output is converted to a digital signal with greater
than 75 dB of dynamic range, all operating on a single 3 V
power supply. This results in an LSB size for small audio signals of about 216 µV. The typical idle channel noise level of
this device is less than one LSB. In addition to the dynamic
range of the codec–filter function of this device, the input
gain–setting op amp has the capability of greater than 30 dB
of gain intended for an electret microphone interface.
This device was designed for ease of implementation, but
due to the large dynamic range and the noisy nature of the
environment for this device (digital switches, radio tele-
MC145481
9
phones, DSP front–end, etc.) special care must be taken to
assure optimum analog transmission performance.
PC BOARD MOUNTING
It is recommended that the device be soldered to the PC
board for optimum noise performance. If the device is to be
used in a socket, it should be placed in a low parasitic pin
inductance (generally, low–profile) socket.
POWER SUPPLY, GROUND, AND NOISE
CONSIDERATIONS
This device is intended to be used in switching applications which often require plugging the PC board into a rack
with power applied. This is known as ‘‘hot–rack insertion.’’ In
these applications care should be taken to limit the voltage
on any pin from going positive of the VDD pins, or negative of
the VSS pins. One method is to extend the ground and power
contacts of the PCB connector. The device has input protection on all pins and may source or sink a limited amount of
current without damage. Current limiting may be accomplished by series resistors between the signal pins and the
connector contacts.
The most important considerations for PCB layout deal
with noise. This includes noise on the power supply, noise
generated by the digital circuitry on the device, and cross
coupling digital or radio frequency signals into the audio signals of this device. The best way to prevent noise is to:
1. Keep digital signals as far away from audio signals as
possible.
2. Keep radio frequency signals as far away from the audio
signals as possible.
3. Use short, low inductance traces for the audio circuitry
to reduce inductive, capacitive, and radio frequency
noise sensitivities.
4. Use short, low inductance traces for digital and RF
circuitry to reduce inductive, capacitive, and radio
frequency radiated noise.
5. Bypass capacitors should be connected from the VDD,
VAG Ref, and VAG pins to VSS with minimal trace length.
Ceramic monolithic capacitors of about 0.1 µF are
acceptable for the VDD and VAG Ref pins to decouple the
device from its own noise. The VDD capacitor helps
supply the instantaneous currents of the digital circuitry
in addition to decoupling the noise which may be
generated by other sections of the device or other
circuitry on the power supply. The VAG Ref decoupling
capacitor is effecting a low–pass filter to isolate the
mid–supply voltage from the power supply noise generated on–chip as well as external to the device. The VAG
decoupling capacitor should be about 0.01 µF. This
helps to reduce the inpedance of the VAG pin to VSS at
frequencies above the bandwidth of the VAG generator,
which reduces the susceptibility to RF noise.
MC145481
10
6. Use a short, wide, low inductance trace to connect the
VSS ground pin to the power supply ground. The VSS pin
is the digital ground and the most negative power supply
pin for the analog circuitry. All analog signal processing
is referenced to the VAG pin, but because digital and RF
circuitry will probably be powered by this same ground,
care must be taken to minimize high frequency noise in
the VSS trace. Depending on the application, a double–
sided PCB with a VSS ground plane connecting all of the
digital and analog VSS pins together would be a good
grounding method. A multilayer PC board with a ground
plane connecting all of the digital and analog VSS pins
together would be the optimal ground configuration.
These methods will result in the lowest resistance and
the lowest inductance in the ground circuit. This is
important to reduce voltage spikes in the ground circuit
resulting from the high speed digital current spikes. The
magnitude of digitally induced voltage spikes may be
hundreds of times larger than the analog signal the
device is required to digitize.
7. Use a short, wide, low inductance trace to connect the
V DD power supply pin to the 3 V power supply.
Depending on the application, a double–sided PCB with
VDD bypass capacitors to the VSS ground plane, as
described above, may complete the low impedance
coupling for the power supply. For a multilayer PC board
with a power plane, connecting all of the V DD pins to the
power plane would be the optimal power distribution
method. The integrated circuit layout and packaging
considerations for the 3 V V DD power circuit are
essentially the same as for the VSS ground circuit.
8. The VAG pin is the reference for all analog signal
processing. In some applications the audio signal to be
digitized may be referenced to the VSS ground. To
reduce the susceptibility to noise at the input of the ADC
section, the three–terminal op amp may be used in a
differential to single–ended circuit to provide level
conversion from the VSS ground to the VAG ground with
noise cancellation. The op amp may be used for more
than 30 dB of gain in microphone interface circuits, which
will require a compact layout with minimum trace lengths
as well as isolation from noise sources. It is recommended that the layout be as symmetrical as possible to
avoid any imbalances which would reduce the noise
cancelling benefits of this differential op amp circuit.
Refer to the application schematics for examples of this
circuitry.
If possible, reference audio signals to the VAG pin
instead of to the VSS pin. Handset receivers and telephone line interface circuits using transformers may be
audio signal referenced completely to the VAG pin. Refer to the application schematics for examples of this
circuitry. The VAG pin cannot be used for ESD or line
protection.
MOTOROLA
MAXIMUM RATINGS (Voltages Referenced to VSS Pin)
Rating
Symbol
Value
Unit
VDD
– 0.5 to 6
V
Voltage on Any Analog Input or Output Pin
VSS – 0.3 to VDD + 0.3
V
Voltage on Any Digital Input or Output Pin
VSS – 0.3 to VDD + 0.3
V
TA
– 40 to + 85
°C
Tstg
– 85 to +150
°C
DC Supply Voltage
Operating Temperature Range
Storage Temperature Range
POWER SUPPLY (TA = – 40 to + 85°C)
Min
Typ
Max
Unit
2.7
3.0
5.25
V
(No Load, PI ≥ VDD – 0.5 V)
(No Load, PI ≤ VDD – 1.0 V)
—
—
2.3
2.5
—
—
mA
Power–Down Current (VIH for Logic Levels
PDI = VSS
Must be ≥ VDD – 0.5 V)
FST and FSR = VSS, PDI = VDD
—
—
0.001
0.01
0.1
0.1
mA
Symbol
Min
Max
Unit
Characteristics
DC Supply Voltage
Active Power Dissipation (VDD = 3 V)
DIGITAL LEVELS (VDD = 2.7 to 3.6 V, VSS = 0 V, TA = – 40 to + 85°C)
Characteristics
Input Low Voltage
VIL
—
0.6
V
Input High Voltage
VIH
2.2
—
V
Output Low Voltage (DT Pin, IOL= 1.6 mA)
VOL
—
0.4
V
Output High Voltage (DT Pin, IOH = – 1.6 mA)
VOH
VDD – 0.5
—
V
Input Low Current (VSS ≤ Vin ≤ VDD)
IIL
– 10
+ 10
µA
Input High Current (VSS ≤ Vin ≤ VDD)
IIH
– 10
+ 10
µA
Output Current in High Impedance State (VSS ≤ DT ≤ VDD)
IOZ
– 10
+ 10
µA
Cin
—
10
pF
Cout
—
15
pF
Input Capacitance of Digital Pins (Except DT)
Input Capacitance of DT Pin when High–Z
MOTOROLA
MC145481
11
ANALOG ELECTRICAL CHARACTERISTICS (VDD = 2.7 to 3.6 V, VSS = 0 V, TA = – 40 to + 85°C)
Min
Typ
Max
Unit
Input Current
TI+, TI–
—
± 0.1
± 1.0
µA
Input Resistance to VAG (VAG – 0.3 V ≤ Vin ≤ VAG + 0.3 V)
TI+, TI–
10
—
—
MΩ
Input Capacitance
TI+, TI–
—
—
10
pF
Input Offset Voltage of TG Op Amp
TI+, TI–
—
—
±5
mV
Input Common Mode Voltage Range
TI+, TI–
1.2
VDD – 1.2
V
Input Common Mode Rejection Ratio
TI+, TI–
—
TBD
—
dB
Gain Bandwidth Product (10 kHz) of TG Op Amp (RL ≥ 10 kΩ)
—
3000
—
kHz
DC Open Loop Gain of TG Op Amp (RL ≥ 10 kΩ)
—
95
—
dB
Equivalent Input Noise (C–Message) Between TI+ and TI– at TG
—
TBD
—
dBrnC
Output Load Capacitance for TG Op Amp
0
—
100
pF
(RL = 2 kΩ to VAG)
0.4
—
VDD – 0.4
V
Output Current (0.5 V ≤ Vout ≤ VDD – 0.5 V)
TG, RO–
TBD
—
—
mA
Output Load Resistance to VAG
Characteristics
Output Voltage Range for TG
TG, RO–
2
—
—
kΩ
Output Impedance
RO–
—
1
—
Ω
Output Load Capacitance
RO–
0
—
200
pF
—
—
± 25
mV
VDD/2 – 0.05
VDD/2
VDD/2 + 0.05
V
± 2.0
—
—
mA
TBD
TBD
TBD
TBD
—
—
dBC
± 1.0
µA
DC Output Offset Voltage of RO– Referenced to VAG
VAG Output Voltage Referenced to VSS (No Load)
VAG Output Current with ± 25 mV Change in Output Voltage
Power Supply Rejection Ratio , VDD = 3.0 V
(0 to 100 kHz @100 mVrms Applied to VDD,
C–Message Weighting, All Analog Signals
Referenced to VAG Pin)
Transmit
Receive
Power Drivers PI, PO+, PO–
Input Current (VAG – 0.3 V ≤ PI ≤ VAG + 0.3 V)
PI
—
± 0.05
Input Resistance (VAG – 0.3 V ≤ PI ≤ VAG + 0.3 V)
PI
10
—
—
MΩ
Input Offset Voltage
PI
—
—
± 20
mV
—
—
± 50
mV
TBD
—
—
mA
PO+ or PO– Output Resistance (Inverted Unity Gain for PO–)
—
1
—
Ω
Gain Bandwidth Product (10 kHz, Open Loop for PO–)
—
1000
—
kHz
Output Offset Voltage of PO+ Relative to PO– (Inverted Unity Gain for PO–)
Output Current (VSS + 0.4 V ≤ PO+ or PO– ≤ VDD – 0.4 V)
Load Capacitance (PO+ or PO– to VAG, or PO+ to PO–)
Gain of PO+ Relative to PO– (RL = 300 Ω, + 3 dBm0 @ 1 kHz)
Total Signal to Distortion at PO+ and PO– with a Differential Load of:
300 Ω
100 nF in series with ≥ 20 Ω
≥ 100 Ω
Power Supply Rejection Ratio
(0 to 25 kHz @ 50 mVrms Applied to VDD.
PO– Connected to PI. Differential or Measured
Referenced to VAG Pin.)
MC145481
12
0 to 4 kHz
4 to 25 kHz
0
—
1000
pF
– 0.2
0
+ 0.2
dB
45
—
—
60
40
40
—
—
—
dBC
TBD
—
TBD
TBD
—
—
dB
MOTOROLA
ANALOG TRANSMISSION PERFORMANCE
(VDD = 2.7 to 3.6 V, VSS = 0 V, All Analog Signals Referenced to VAG, 0 dBm0 = 0.436 Vrms = – 5 dBm @ 600 Ω, FST = FSR = 8 kHz,
BCLKT = MCLK = 2.048 MHz Synchronous Operation, TA = – 40 to + 85°C, Unless Otherwise Noted)
A/D
Characteristics
Ch
i i
Peak Single Frequency Tone Amplitude without Clipping
Tmax
Min
Typ
D/A
Max
Min
Typ
Max
Units
U i
—
0.886
—
—
0.886
—
Vpk
– 0.25
—
+ 0.25
– 0.25
—
+ 0.25
dB
—
—
TBD
TBD
—
—
—
—
TBD
TBD
—
—
dB
—
TBD
—
—
TBD
—
dB
– 0.30
– 0.8
– 1.3
—
—
—
+ 0.25
+ 0.50
+ 0.80
– 0.25
– 0.50
– 0.80
—
—
—
+ 0.25
+ 0.50
+ 0.80
dB
– 0.30
– 0.65
– 1.00
—
—
—
+ 0.25
+ 0.30
+ 0.45
– 0.25
– 0.30
– 0.45
—
—
—
+ 0.25
+ 0.30
+ 0.45
dB
+ 3 dBm0
0 to – 30 dBm0
– 40 dBm0
– 45 dBm0
34
35
28.5
25
—
—
—
—
—
—
—
—
34
36
28.5
25
—
—
—
—
—
—
—
—
dBC
– 3 dBm0
– 6 to – 27 dBm0
– 34 dBm0
– 40 dBm0
– 55 dBm0
30
35
34
28
13.5
—
—
—
—
—
—
—
—
—
—
30
35.5
34.5
28.5
14
—
—
—
—
—
—
—
—
—
—
dB
—
—
—
—
19
– 68
—
—
—
—
14
– 76
dBr nc0
dBm0p
—
—
—
—
– 1.0
– 0.20
– 0.20
– 0.35
– 0.9
—
—
—
—
—
—
–3
—
—
—
—
—
–3
—
—
– 40
– 30
– 26
—
– 0.4
+ 0.20
+ 0.20
+ 0.20
0
—
– 14
– 32
– 0.5
– 0.5
– 0.5
– 0.5
– 0.5
– 0.20
– 0.20
– 0.35
– 0.9
—
—
—
—
—
—
—
—
—
—
—
—
–3
—
—
0
0
0
0
0
+ 0.20
+ 0.20
+ 0.20
0
—
– 14
– 30
dB
In–Band Spurious (1.02 kHz @ 0 dBm0, Transmit and Receive)
300 to 3200 Hz
—
—
TBD
—
—
TBD
Out–of–Band Spurious at VAG Ref (300 to 3400 Hz @ 0 dBm0 in)
4600 to 7600 Hz
7600 to 8400 Hz
8400 to 100,000 Hz
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
– 30
– 40
– 30
dB
Idle Channel Noise Selective (8 kHz, Input = VAG, 30 Hz Bandwidth)
—
—
—
—
—
– 70
dBm0
Absolute Delay (1600 Hz)
—
—
315
—
—
205
µs
—
—
—
—
—
—
—
—
—
—
—
—
—
—
210
130
70
35
70
95
145
– 40
– 40
– 40
– 30
—
—
—
—
—
—
—
—
—
—
—
—
—
—
85
110
175
µs
Crosstalk of 1020 Hz @ 0 dBm0 from A/D or D/A (Note 2)
—
—
– 75
—
—
– 75
dB
Intermodulation Distortion of Two Frequencies of Amplitudes
(– 4 to – 21 dBm0 from the Range 300 to 3400 Hz)
—
—
– 41
—
—
– 41
Absolute Gain (0 dBm0 @ 1.02 kHz, TA = 25°C, VDD = 3.0 V)
Absolute Gain Variation with Temperature
0 to + 70°C
– 40 to + 85°C
Absolute Gain Variation with Power Supply (TA = 25°C)
Gain vs Level Tone (Mu–Law, Relative to – 10 dBm0, 1.02 kHz)
+ 3 to – 40 dBm0
– 40 to – 50 dBm0
– 50 to – 55 dBm0
Gain vs Level Pseudo Noise, CCITT G.712
(A–Law, Relative to – 10 dBm0)
– 10 to – 40 dBm0
– 40 to – 50 dBm0
– 50 to – 55 dBm0
Total Distortion, 1.02 kHz Tone (Mu–Law, C–Message Weighting)
Total Distortion, Pseudo Noise, CCITT G.714 (A–Law)
Idle Channel Noise (For A/D, See Note 1)
(Mu–Law, C–Message Weighted)
(A–Law, Psophometric Weighted)
Frequency Response (Relative to 1.02 kHz @ 0 dBm0)
15 Hz
50 Hz
60 Hz
165 Hz
200 Hz
300 to 3000 Hz
3000 to 3200 Hz
3300 Hz
3400 Hz
3600 Hz
4000 Hz
4600 Hz to 100 kHz
Group Delay Referenced to 1600 Hz
500 to 600 Hz
600 to 800 Hz
800 to 1000 Hz
1000 to 1600 Hz
1600 to 2600 Hz
2600 to 2800 Hz
2800 to 3000 Hz
dB
dB
NOTES:
1. Extrapolated from a 1020 Hz @ – 50 dBm0 distortion measurement to correct for encoder enhancement.
2. Selectively measured while stimulated with 2667 Hz @ – 50 dBm0.
MOTOROLA
MC145481
13
DIGITAL SWITCHING CHARACTERISTICS, LONG FRAME SYNC AND SHORT FRAME SYNC
(VDD = 2.7 to 3.6 V, VSS = 0 V, All Digital Signals Referenced to VSS, TA = – 40 to + 85°C, CL = 150 pF, Unless Otherwise Noted)
Ref.
No.
Characteristics
Min
Typ
Max
Unit
1
Master Clock Frequency for MCLK
—
—
—
—
—
—
—
256
512
1536
1544
2048
2560
4096
—
—
—
—
—
—
—
kHz
1
MCLK Duty Cycle for 256 kHz Operation
45
—
55
%
2
Minimum Pulse Width High for MCLK (Frequencies of 512 kHz or Greater)
50
—
—
ns
3
Minimum Pulse Width Low for MCLK (Frequencies of 512 kHz or Greater)
50
—
—
ns
4
Rise Time for All Digital Signals
—
—
50
ns
5
Fall Time for All Digital Signals
—
—
50
ns
6
Setup Time from MCLK Low to FST High
50
—
—
ns
7
Setup Time from FST High to MCLK Low
50
—
—
ns
8
Bit Clock Data Rate for BCLKT or BCLKR
64
—
4096
kHz
9
Minimum Pulse Width High for BCLKT or BCLKR
50
—
—
ns
10
Minimum Pulse Width Low for BCLKT or BCLKR
50
—
—
ns
11
Hold Time from BCLKT (BCLKR) Low to FST (FSR) High
20
—
—
ns
12
Setup Time for FST (FSR) High to BCLKT (BCLKR) Low
80
—
—
ns
13
Setup Time from DR Valid to BCLKR Low
0
—
—
ns
14
Hold Time from BCLKR Low to DR Invalid
50
—
—
ns
LONG FRAME SPECIFIC TIMING
15
Hold Time from 2nd Period of BCLKT (BCLKR) Low to FST (FSR) Low
50
—
—
ns
16
Delay Time from FST or BCLKT, Whichever is Later, to DT for Valid MSB Data
—
—
60
ns
17
Delay Time from BCLKT High to DT for Valid Chord and Step Bit Data
—
—
60
ns
18
Delay Time from the Later of the 8th BCLKT Falling Edge, or the Falling Edge
of FST to DT Output High Impedance
10
—
60
ns
19
Minimum Pulse Width Low for FST or FSR
50
—
—
ns
SHORT FRAME SPECIFIC TIMING
20
Hold Time from BCLKT (BCLKR) Low to FST (FSR) Low
50
—
—
ns
21
Setup Time from FST (FSR) Low to MSB Period of BCLKT (BCLKR) Low
50
—
—
ns
22
Delay Time from BCLKT High to DT Data Valid
10
—
60
ns
23
Delay Time from the 8th BCLKT Low to DT Output High Impedance
10
—
60
ns
MC145481
14
MOTOROLA
1
7
4
3
6
5
2
MCLK
8
1
BCLKT
2
3
4
5
12
6
7
8
9
9
11
15
10
FST
16
18
17
18
16
MSB
DT
CH1
CH2
CH3
ST1
ST2
ST3
LSB
8
1
BCLKR
2
3
11
4
5
15
6
7
8
9
9
12
10
FSR
14
13
DR
MSB
CH1
CH2
CH3
ST1
ST2
ST3
LSB
Figure 3. Long Frame Sync Timing
MOTOROLA
MC145481
15
1
7
4
3
6
5
2
MCLK
12
8
1
BCLKT
2
3
4
5
6
7
8
9
9
20
21
11
10
FST
23
22
22
MSB
DT
CH1
CH2
CH3
ST1
ST2
ST3
LSB
8
1
BCLKR
2
3
4
5
20
6
7
8
9
9
21
11
10
12
FSR
14
13
DR
MSB
CH1
CH2
CH3
ST1
ST2
ST3
LSB
Figure 4. Short Frame Sync Timing
MC145481
16
MOTOROLA
DIGITAL SWITCHING CHARACTERISTICS FOR IDL MODE
(VDD = 2.7 to 3.6 V, TA = – 40 to + 85°C, CL = 150 pF, See Figure 5 and Note 1)
Ref.
No.
Characteristics
Min
Max
Unit
31
Time Between Successive IDL Syncs
Note 2
32
Hold Time of IDL SYNC After Falling Edge of IDL CLK
20
—
ns
33
Setup Time of IDL SYNC Before Falling Edge IDL CLK
60
—
ns
34
IDL Clock Frequency
256
4096
kHz
35
IDL Clock Pulse Width High
50
—
ns
36
IDL Clock Pulse Width Low
50
—
ns
37
Data Valid on IDL RX Before Falling Edge of IDL CLK
20
—
ns
38
Data Valid on IDL RX After Falling Edge of IDL CLK
75
—
ns
39
Falling Edge of IDL CLK to High–Z on IDL TX
10
50
ns
40
Rising Edge of IDL CLK to Low–Z and Data Valid on IDL TX
10
60
ns
41
Rising Edge of IDL CLK to Data Valid on IDL TX
—
50
ns
NOTES:
1. Measurements are made from the point at which the logic signal achieves the guaranteed minimum or maximum logic level.
2. In IDL mode, both transmit and receive 8–bit PCM words are accessed during the B1 channel, or both transmit and receive 8–bit PCM words
are accessed during the B2 channel as shown in Figure 5. IDL accesses must occur at a rate of 8 kHz (125 µs interval).
31
IDLE SYNC
(FST)
32
33
34
32
35
IDL CLOCK
(BCLKT)
1
2
3
4
5
6
7
8
IDL TX
(DT)
10
11
12
13
41
41
15
16
17
18
19
1
2
39
40
MSB CH1 CH2 CH3 ST1 ST2 ST3 LSB
MSB CH1 CH2 CH3 ST1 ST2 ST3 LSB
38
38
37
IDL RX
(DR)
14
39
36
40
9
37
MSB CH1 CH2 CH3 ST1 ST2 ST3 LSB
MSB CH1 CH2 CH3 ST1 ST2 ST3
LSB
Figure 5. IDL Interface Timing
MOTOROLA
MC145481
17
DIGITAL SWITCHING CHARACTERISTICS FOR GCI MODE
(VDD = 2.7 to 3.6 V, TA = – 40 to + 85°C, CL = 150 pF, See Figure 6 and Note 1)
Ref.
No.
Characteristics
Min
Max
Unit
42
Time Between Successive FSC Pulses
Note 2
43
DCL Clock Frequency
512
6176
kHz
44
DCL Clock Pulse Width High
50
—
ns
45
DCL Clock Pulse Width Low
50
—
ns
46
Hold Time of FSC After Falling Edge of DCL
20
—
ns
47
Setup Time of FSC to DCL Falling Edge
60
—
ns
48
Rising Edge of DCL (After Rising Edge of FSC) to Low Impedance and Valid Data of Dout
—
60
ns
49
Rising Edge of FSC (While DCL is High) to Low Impedance and Valid Data of Dout
—
60
ns
50
Rising Edge of DCL to Valid Data on Dout
—
60
ns
51
Second DCL Falling Edge During LSB to High Impedance of Dout
10
50
ns
52
Setup Time of Din Before Rising Edge of DCL
20
—
ns
53
Hold Time of Din After DCL Rising Edge
—
60
ns
NOTES:
1. Measurements are made from the point at which the logic signal achieves the guaranteed minimum or maximum logic level.
2. In GCI mode, both transmit and receive 8–bit PCM words are accessed during the B1 channel, or both transmit and receive 8–bit PCM words
are accessed during the B2 channel as shown in Figure 6. GCI accesses must occur at a rate of 8 kHz (125 µs interval).
42
FSC
(FST)
1 2 3 4 5 6
7 8 9 10 11 12 13 14 15 16
17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34
DCL
(BCLKT)
51
50
MSB
Dout (DT)
CH1
CH2
CH3
ST1
ST2
ST3
50
48
49
LSB
MSB CH1
53
52
MSB
Din (DR)
CH1
CH2
CH3
CH3
ST1
ST2
ST3
LSB
MSB
CH1
CH2
ST2
ST3 LSB
ST2
ST3
53
52
CH2
ST1
51
CH3
ST1
LSB
46
FSC
(FST)
46
43
47
DCL
(BCLKT)
44
1
2
3
4
49
45
48
Dout (DT)
MSB
52
Din (DR)
5
CH1
53
MSB
CH1
Figure 6. GCI Interface Timing
MC145481
18
MOTOROLA
1
0.1 µF
2
3
AUDIO OUT
4
–
+
5
6
+3V
7
0.1 µF
8
9
10
VAG Ref
VAG
RO–
TI+
PI
TI–
TG
PO–
17
VDD
VSS
FSR
FST
BCLKT
BCLKR
MCLK
PDI
10 kΩ
1.0 µF
ANALOG IN
Y
18
Mu/A 16
DT
10 kΩ
19
PO+
DR
0.01 µF
20
10 kΩ
10 kΩ
1.0 µF
+3V
15
14
8 kHz
13
PCM OUT
12
2.048 MHz
11
PCM IN
Figure 7. MC145481 Test Circuit — Signals Referenced to VAG Pin
0.1 µF
1
AUDIO OUT
20 k
RL ≥ 2 kΩ
68 µF
AUDIO OUT
RL ≥ 150 Ω
20 k
+
2
3
4
5
10 kΩ
+3V
6
7
0.1 µF
8
9
10
VAG Ref
VAG
RO–
TI+
PI
TI–
PO–
TG
PO+
VSS
FSR
FST
DR
DT
BCLKR
PDI
BCLKT
MCLK
10 kΩ
10 kΩ
19
1.0 µF
18
17
Mu/A 16
VDD
0.01 µF
20
10 kΩ
+3V
10 kΩ
ANALOG IN
1.0 µF
15
14
13
12
Y
8 kHz
PCM OUT
2.048 MHz
11
PCM IN
Figure 8. MC145481 Test Circuit — Signals Referenced to VSS
MOTOROLA
MC145481
19
2.048 MHz
18 pF
18 pF
10 MΩ
+5V
VCC
R
OSC IN
OSC
OSC
OUT 1 OUT 2
MC74HC4060
0.1 µF
GND
2.048 MHz
(BCLKT, BCLKR, MCLK)
300 Ω
Q8
8 kHz
(FST, FSR)
Q4
+5V
J
VCC
Q
J
1/2 MC74HC73
K
Q
GND R
Q
1/2 MC74HC73
K
Q
R
+5V
8 kHz
256
1
2
3
4
5
6
7
8
9
2.048 MHz
Figure 9. Long Frame Sync Clock Circuit for 2.048 MHz
+3 V
1 kΩ
SIDETONE
0.1 µF
0.01 µF
68 µF
1 kΩ
420 pF
1
2
3
4
REC
5
+3V
6
7
0.1 µF
8
9
10
VAG Ref
VAG
20
RO–
TI+
PI
TI–
PO–
TG
PO+
Mu/A
VDD
VSS
FSR
FST
DR
DT
13
BCLKT
12
BCLKR
PDI
MCLK
75 kΩ
19
17
15
MIC
1 kΩ
18
16
1 kΩ 1.0 µF
75 kΩ
+3V
1.0 µF
420 pF
14
8 kHz
PCM OUT
2.048 MHz
11
PCM IN
Figure 10. MC145481 Analog Interface to Handset
MC145481
20
MOTOROLA
1.0 µF
R0 = 600 Ω
10 kΩ
0.1 µF
TIP
1
20 k
N = 0.5
1/4 R0
20 k
N = 0.5
2
3
4
5
– 48 V
N = 0.5
+3V
6
7
RING
0.1 µF
8
9
10
VAG Ref
VAG
RO–
TI+
PI
TI–
PO–
TG
PO+
Mu/A
VDD
VSS
FSR
FST
DR
BCLKR
PDI
DT
BCLKT
MCLK
20
19
18
17
0.01 µF
20 kΩ
16
15
14
13
12
8 kHz
PCM OUT
2.048 MHz
11
PCM IN
Figure 11. MC145481 Step–Up Transformer Line Interface
MOTOROLA
MC145481
21
PACKAGE DIMENSIONS
DW SUFFIX
SOG PACKAGE
CASE 751D–04
NOTES:
1. DIMENSIONING AND TOLERANCING PER
ANSI Y14.5M, 1982.
2. CONTROLLING DIMENSION: MILLIMETER.
3. DIMENSIONS A AND B DO NOT INCLUDE
MOLD PROTRUSION.
4. MAXIMUM MOLD PROTRUSION 0.150
(0.006) PER SIDE.
5. DIMENSION D DOES NOT INCLUDE
DAMBAR PROTRUSION. ALLOWABLE
DAMBAR PROTRUSION SHALL BE 0.13
(0.005) TOTAL IN EXCESS OF D DIMENSION
AT MAXIMUM MATERIAL CONDITION.
–A–
20
11
–B–
10X
P
0.010 (0.25)
1
M
B
M
10
20X
D
0.010 (0.25)
M
T A
B
S
DIM
A
B
C
D
F
G
J
K
M
P
R
J
S
F
R
X 45 _
C
SEATING
PLANE
–T–
18X
G
MILLIMETERS
MIN
MAX
12.65
12.95
7.40
7.60
2.35
2.65
0.35
0.49
0.50
0.90
1.27 BSC
0.25
0.32
0.10
0.25
0_
7_
10.05
10.55
0.25
0.75
INCHES
MIN
MAX
0.499
0.510
0.292
0.299
0.093
0.104
0.014
0.019
0.020
0.035
0.050 BSC
0.010
0.012
0.004
0.009
0_
7_
0.395
0.415
0.010
0.029
M
K
SD SUFFIX
SSOP
CASE 940C–02
20
NOTES:
1. CONTROLLING DIMENSION: MILLIMETER.
2. DIMENSIONS AND TOLERANCES PER ANSI
Y14.5M, 1982.
3. DIMENSIONS A AND B DO NOT INCLUDE
MOLD FLASH OR PROTRUSIONS AND ARE
MEASURED AT THE PARTING LINE. MOLD
FLASH OR PROTRUSIONS SHALL NOT
EXCEED 0.15MM PER SIDE.
4. DIMENSION IS THE LENGTH OF TERMINAL
FOR SOLDERING TO A SUBSTRATE.
5. TERMINAL POSITIONS ARE SHOWN FOR
REFERENCE ONLY.
6. THE LEAD WIDTH DIMENSION DOES NOT
INCLUDE DAMBAR PROTRUSION.
ALLOWABLE DAMBAR PROTRUSION SHALL
BE 0.08MM TOTAL IN EXCESS OF THE LEAD
WIDTH DIMENSION.
11
B
–R–
1
C
10
0.076 (0.003)
A
–P–
N
0.25 (0.010)
M
R
M
L
J
M
G
H
MC145481
22
D
0.120 (0.005)
F
NOTE 4
M
T P
S
DIM
A
B
C
D
F
G
H
J
L
M
N
MILLIMETERS
MIN
MAX
7.10
7.30
5.20
5.38
1.75
1.99
0.25
0.38
0.65
1.00
0.65 BSC
0.59
0.75
0.10
0.20
7.65
7.90
0_
8_
0.05
0.21
INCHES
MIN
MAX
0.280
0.287
0.205
0.212
0.069
0.078
0.010
0.015
0.026
0.039
0.026 BSC
0.023
0.030
0.004
0.008
0.301
0.311
0_
8_
0.002
0.008
MOTOROLA
Motorola reserves the right to make changes without further notice to any products herein. Motorola makes no warranty, representation or guarantee regarding
the suitability of its products for any particular purpose, nor does Motorola assume any liability arising out of the application or use of any product or circuit,
and specifically disclaims any and all liability, including without limitation consequential or incidental damages. “Typical” parameters can and do vary in different
applications. All operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. Motorola does
not convey any license under its patent rights nor the rights of others. Motorola products are not designed, intended, or authorized for use as components in
systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of
the Motorola product could create a situation where personal injury or death may occur. Should Buyer purchase or use Motorola products for any such
unintended or unauthorized application, Buyer shall indemnify and hold Motorola and its officers, employees, subsidiaries, affiliates, and distributors harmless
against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death
associated with such unintended or unauthorized use, even if such claim alleges that Motorola was negligent regarding the design or manufacture of the part.
Motorola and
are registered trademarks of Motorola, Inc. Motorola, Inc. is an Equal Opportunity/Affirmative Action Employer.
How to reach us:
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51 Ting Kok Road, Tai Po, N.T., Hong Kong. 852–26629298
MOTOROLA
◊
*MC145481/D*
MC145481/D
MC145481
23