MITEL MT9092AP

ISO2-CMOS ST-BUS FAMILY

MT9092
Digital Telephone with HDLC (HPhone-II)
Features
ISSUE 2
•
Programmable µ-Law/A-Law codec and filters
•
Programmable CCITT (G.711)/sign-magnitude
coding
•
Programmable transmit, receive and side-tone
gains
•
DSP-based:
•
i) Speakerphone switching algorithm
ii) DTMF and single tone generator
iii) Tone Ringer
Differential interface to telephony transducers
•
Differential audio paths
•
Single 5 volt power supply
•
X.25 Level 2 HDLC data formatting
Applications
•
Fully featured digital telephone sets
•
Cellular phone sets
•
Local area communications stations
DSTo
DSTi
F0i
Digital Signal Processor
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22.5/-72dB
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Tx
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May 1995
Ordering Information
MT9092AP
44 Pin PLCC
-40°C to +85°C
Description
The MT9092 HPhone-II is a fully featured integrated
digital telephone circuit which includes an HDLC
data formatter. Voice band signals are converted to
digital PCM and vice versa by a switched capacitor
Filter/Codec. The Filter/Codec uses an ingenious
differential architecture to achieve low noise
operation over a wide dynamic range with a single
5V supply. A Digital Signal Processor provides
handsfree speaker-phone operation. The DSP is
also used to generate tones (DTMF, Ringer and Call
Progress) and control audio gains. Internal registers
are accessed through a serial microport conforming
to INTEL MCS-51™ specifications. The device is
fabricated in Mitel's low power ISO2-CMOS
technology.
Filter/Codec Gain
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MICTransducer
Interface
MIC+
MM+
C4i
VSSD
HSPKR+
STATUS
Control
Registers
C-Channel
Registers
HSPKRSPKR+
VDD
VSSA
SPKR-
HDLC
VSS
SPKR
New Call
Tone
Generator
Timing
Circuits
VBias
VRef
S/P &
P/S
Converter
LCD Driver
S1
S12
BP
Serial
Port
(MCS-51
Compatible)
DATA 2
DATA 1
SCLK
CS
IRQ
WD PWRST IC
Figure 1 - Functional Block Diagram
7-3
6
5
4
3
2
1
44
43
42
41
40
PWRST
IC
VRef
VBias
NC
M+
MVSSA
MIC+
MICVSS SPKR
MT9092
7
8
9
10
11
12
13
14
15
16
17
39
38
37
36
35
34
33
32
31
30
29
SPKR+
SPKRHSPKR+
HSPKRVDD
BP
S12
S11
S10
S9
S8
IC
NC
NC
VSSD
S1
S2
S3
S4
S5
S6
S7
18
19
20
21
22
23
24
25
26
27
28
DSTi
DSTo
C4i
F0i
VSSD
IRQ
SCLK
DATA 2
DATA 1
CS
WD
44 PIN PLCC
Figure 2 - Pin Connections
Pin Description
Pin
#
Name
1
M+
Non-Inverting Microphone (Input). Non-inverting input to microphone amplifier from the
handset microphone.
2
NC
No Connect. No internal connection to this pin.
3
VBias
Bias Voltage (Output). (VDD/2) volts is available at this pin for biasing external amplifiers.
Connect 0.1 µF capacitor to VSSA.
4
VRef
Reference voltage for codec (Output). Nominally [(VDD/2)-1.5] volts. Used internally.
Connect 0.1 µF capacitor to VSSA.
5
IC
6
7-4
Description
Internal Connection. Tie externally to VSS for normal operation.
PWRST Power-up Reset (Input). CMOS compatible input with Schmitt Trigger (active low).
7
DSTi
ST-BUS Serial Stream (Input). 2048 kbit/s input stream composed of 32 eight bit channels;
the first four of which are used by the MT9092. Input level is TTL compatible.
8
DSTo
ST-BUS Serial Stream (Output). 2048 kbit/s output stream composed of 32 eight bit
channels. The MT9092 sources digital signals during the appropriate channel, time coincident
with the channels used for DSTi.
9
C4i
4096 kHz Clock (Input). CMOS level compatible.
10
F0i
Frame Pulse (Input). CMOS level compatible. This input is the frame synchronization pulse
for the 2048 kbit/s ST-BUS stream.
11
VSSD
Digital Ground . Nominally 0 volts.
12
IRQ
Interrupt Request (Open Drain Output). An active low output indicating an unmasked HDLC
interrupt event. Requires 1 kΩ pull-up to VDD.
13
SCLK
Serial Port Synchronous Clock (Input). Data clock for MCS-51 compatible microport. TTL
level compatible.
MT9092
Pin Description (continued)
Pin
#
Name
Description
14
DATA 2 Serial Data Transmit. In an alternate mode of operation, this pin is used for data transmit
from MT9092. In the default mode, serial data transmit and receive are performed on the
DATA 1 pin and DATA 2 is tri-stated.
15
DATA 1 Bidirectional Serial Data. Port for microprocessor serial data transfer compatible with MCS51 standard (default mode). In an alternate mode of operation , this pin becomes the data
receive pin only and data transmit is performed on the DATA 2 pin. Input level TTL compatible.
16
CS
Chip Select (Input). This input signal is used to select the device for microport data
transfers. Active low. (TTL level compatible.)
17
WD
Watchdog (Output). Watchdog timer output. Active high.
18
IC
Internal Connection. Tie externally to VSS for normal operation.
19,
20
NC
No Connection. No internal connection to these pins.
21
VSSD
2233
Digital Ground. Nominally 0 volts.
S1-S12 Segment Drivers (Output). 12 independently controlled, two level, LCD segment drivers. An
in-phase signal, with respect to the BP pin, produces a non-energized LCD segment. An outof-phase signal, with respect to the BP pin, energizes its respective LCD segment.
34
BP
Backplane Drive (Output). A two-level output voltage for biasing an LCD backplane.
35
VDD
Positive Power Supply (Input). Nominally 5 volts.
36
HSPKR- Inverting Handset Speaker (Output). Output to the handset speaker (balanced).
37
HSPKR Non-Inverting Handset Speaker (Output). Output to the handset speaker (balanced).
+
38
SPKR-
39
SPKR+ Non-Inverting Speaker (Output). Output to the speakerphone speaker (balanced).
Inverting Speaker (Output). Output to the speakerphone speaker (balanced).
40
VSS
SPKR
Power Supply Rail for Analog Output Drivers. Nominally 0 Volts.
41
MIC-
Inverting Handsfree Microphone (Input).
pin.
42
MIC+
Non-inverting Handsfree Microphone (Input).
inverting input pin.
43
VSSA
Analog Ground. Nominally 0 V.
44
M-
Handsfree microphone amplifier inverting input
Handsfree microphone amplifier non-
Inverting Microphone (Input). Inverting input to microphone amplifier from the handset
microphone.
NOTES:
Intel and MCS-51 are registered trademarks of Intel Corporation, Santa Clara, CA, USA.
7-5
MT9092
Overview
The functional block diagram of Figure 1 depicts the
main operations performed within the HPhone-II.
Each of these functional blocks will be described in
the sections to follow. This overview will describe
some of the end-user features which may be
implemented as a direct result of the level of
integration found within the HPhone-II.
The main feature required of a digital telephone is to
convert the digital Pulse Code Modulated (PCM)
information, being received by the telephone set, into
an analog electrical signal. This signal is then
applied to an appropriate audio transducer such that
the information is finally converted into intelligible
acoustic energy. The same is true of the reverse
direction where acoustic energy is converted first
into an electrical analog and then digitized (into
PCM) before being transmitted from the set. Along
the way if the signals can be manipulated, either in
the analog or the digital domains, other features
such as gain control, signal generation and filtering
may be added. More complex processing of the
digital signal is also possible and is limited only be
the processing power available. One example of this
processing power may be the inclusion of a complex
handsfree switching algorithm. Finally, most electroacoustic transducers (loudspeakers) require a large
amount of power to develop an effective acoustic
signal. The inclusion of audio amplifiers to provide
this power is required.
The HPhone-II features Digital Signal Processing
(DSP) of the voice encoded PCM, complete Analog/
Digital and Digital/Analog conversion of audio
signals (Filter/CODEC) and an analog interface to
the external world of electro-acoustic devices
(Transducer Interface). These three functional blocks
combine to provide a standard full-duplex telephone
conversation utilizing a common handset. Selecting
transducers for handsfree operation, as well as
allowing the DSP to perform its handsfree switching
algorithm, is all that is required to convert the fullduplex handset conversation into a half-duplex
speakerphone conversation. In each of these
modes, full programmability of the receive path and
side-tone gains is available to set comfortable
listening levels for the user as well as transmit path
gain control for setting nominal transmit levels into
the network.
The HPhone-II’s HDLC block is easy to use in
proprietary signalling protocols such as those within
PABXs and Key Systems. A fully interrupt driven
interface, buffered by 19 byte FIFOs in each
direction,
simplifies
the
microcontroller's
asynchronous access to the D-Channel information.
7-6
The ability to generate tones locally provides the
designer with a familiar method of feedback to the
telephone user as they proceed to set-up, and
ultimately, dismantle a telephone conversation. Also,
as the network slowly evolves from the dial pulse/
DTMF methods to the D-Channel protocols it is
essential that the older methods be available for
backward compatibility. As an example; once a call
has been established, say from your office to your
home, using the D-Channel signalling protocol it may
be necessary to use in-band DTMF signalling to
manipulate your personal answering machine in
order to retrieve messages. Thus the locally
generated tones must be of network quality and not
just a reasonable facsimile. The HPhone-II DSP can
generate the required tone pairs as well as single
tones to accommodate any in-band signalling
requirement.
Each of the programmable parameters within the
functional blocks is accessed through a serial
microcontroller port compatible with Intel MCS-51
specifications.
Functional Description
In this section, each functional block within the
HPhone-II is described along with all of the
associated control/status bits. Each time a control/
status bit(s) is described it is followed by the address
register where it will be found. The reader is referred
to the section titled ‘Register Summary' for a
complete listing of all address map registers, the
control/status bits associated with each register and
a definition of the function of each control/status bit.
The Register Summary is useful for future reference
of control/status bits without the need to locate them
within the text of the functional descriptions.
Filter-CODEC
The Filter/CODEC block implements conversion of
the analog 3.3kHz speech signals to/from the digital
domain compatible with 64kb/s PCM B-Channels.
Selection of companding curves and digital code
assignment are register programmable. These are
CCITT G.711 A-law or µ-Law, with true-sign/
Alternate Digit Inversion or true-sign/Inverted
Magnitude coding, respectively. Optionally, signmagnitude coding may also be selected for
proprietary applications.
The Filter/CODEC block also implements transmit
and receive audio path gains in the analog domain.
These gains are in addition to the digital gain pad
provided in the DSP section and provide an overall
path gain resolution of 0.5dB. A programmable gain,
MT9092
voice side-tone path is also included to provide
proportional transmit speech feedback to the
handset receiver so that a dead sounding handset is
not encountered. Figure 3 depicts the nominal halfchannel and side-tone gains for the HPhone-II.
On PWRST (pin 6) the Filter/CODEC defaults such
that the side-tone path, dial tone filter and 400Hz
transmit filter are off, all programmable gains are set
to 0dB and µ-Law companding is selected. Further,
the Filter/CODEC is powered down due to the PuFC
bit (Transducer Control Register, address 0Eh) being
reset. This bit must be set high to enable the Filter/
CODEC.
The internal architecture is fully differential to provide
the best possible noise rejection as well as to allow a
SERIAL
PORT
DSP GAIN*
FILTER/CODEC
wide dynamic range from a single 5 volt supply
design. This fully differential architecture is
continued into the Transducer Interface section to
provide full chip realization of these capabilites.
A reference voltage (V Ref), for the conversion
requirements of the CODER section, and a bias
voltage (VBias), for biasing the internal analog
sections, are both generated on-chip. V Bias is also
brought to an external pin so that it may be used for
biasing any external gain plan setting amplifiers. A
0.1µF capacitor must be connected from VBias to
analog ground at all times. Likewise, although VRef
may only be used internally, a 0.1µF capacitor from
the VRef pin to ground is required at all times. It is
suggested that the analog ground reference point for
these two capacitors be physically the same point.
TRANSDUCER INTERFACE
µ-Law –6.3 dB
Α-Law –3.7 dB
Receiver
Driver
Receive
PCM
–72 to
+22.5 dB
(1.5dB
steps)
Receive
Filter Gain
0 to –7 dB
(1 dB steps)
Side-tone
–9.96 to
+9.96dB
(3.32 dB steps)
DTMF,
Tone
Ringer &
Handsfree
-6 dB
Handset
Receiver
(150Ω)
-6 dB
HSPKR+
75
HSPKR–
75
Speaker
Phone
Driver
0.2dB*
Speaker Gain
0 to –24 dB
(8 dB steps)
SPKR+
SPKR–
Speakerphone
Speaker
(40Ω nominal)
(32Ω min)
Tone
Ringer
(input
from DSP)
Side-tone
Nominal
Gain
µ-Law –11 dB
Α-Law –18.8 dB
PCM
–72 to
+22.5 dB
(1.5dB
steps)
Transmit
DIGITAL DOMAIN
Transmit
Filter Gain
0 to +7dB
(1 dB steps)
µ-Law 6.1dB
Α-Law 15.4dB
Transmit
Gain
M
U
X
MIC+ Handsfree
MIC– mic
M+
M–
Transmitter
microphone
ANALOG DOMAIN
Internal to Device
External to Device
Note: *gain the same for A-Law and µ−Law
Figure 3 - Audio Gain Partitioning
7-7
MT9092
To facilitate this the VRef and VBias pins are situated
on adjacent pins.
Both of these reside in the General Control Register
(address 0Fh).
The transmit filter is designed to meet CCITT G.714
specifications. The nominal gain for this filter path is
0dB (gain control = 0dB). An anti-aliasing filter is
included. This is a second order lowpass
implementation with a corner frequency at 25kHz.
Attenuation is better than 32dB at 256 kHz and less
than 0.01dB within the passband.
Digital Signal Processor
An optional 400Hz high-pass function may be
included into the transmit path by enabling the Tfhp
bit in the Transducer Control Register (address 0Eh).
This option allows the reduction of transmitted
background noise such as motor and fan noise.
The receive filter is designed to meet CCITT G.714
specifications. The nominal gain for this filter path is
0 dB (gain control = 0dB). Filter response is peaked
to compensate for the sinx/x attenuation caused by
the 8kHz sampling rate.
The Rx filter function can be altered by enabling the
DIAL EN control bit in the Transducer Control
Register (address 0Eh). This causes another
lowpass function to be added, with a 3dB point at
1000Hz. This function is intended to improve the
sound quality of digitally generated dial tone
received as PCM.
Transmit sidetone is derived from the Tx filter and is
subject to the gain control of the Tx filter section.
Sidetone is summed into the receive path after the
Rx filter gain control section so that Rx gain
adjustment will not affect sidetone levels. The sidetone path may be enabled/disabled with the SIDE
EN bit located in the Transducer Control Register
(address 0Eh). See also STG0-STG2 (address 0Bh).
Transmit and receive filter gains are controlled by the
TxFG0-TxFG2 and RxFG0-RxFG2 control bits
respectively. These are located in the FCODEC Gain
Control Register 1 (address 0Ah). Transmit filter gain
is adjustable from 0dB to +7dB and receive filter gain
from 0dB to -7dB, both in 1dB increments.
Side-tone filter gain is controlled by the STG 0-STG2
control bits located in the FCODEC Gain Control
Register 2 (address 0Bh). Side-tone gain is
adjustable from -9.96dB to +9.96dB in 3.32dB
increments.
Law selection for the Filter/CODEC is provided by
the A/µ companding control bit while the coding
scheme is controlled by the sign-mag/CCITT bit.
7-8
The DSP block is located, functionally, between the
serial ST-BUS port and the Filter/CODEC block. Its
main purpose is to provide both a digital gain control
and a half-duplex handsfree switching function. The
DSP will also generate the digital patterns required
to produce standard DTMF signalling tones as well
as single tones and a tone ringer output. A
programmable (ON/OFF) offset null routine may also
be performed on the transmit PCM data stream. The
DSP can generate a ringer tone to be applied to the
speakerphone speaker during normal handset
operation so that the existing call is not interrupted.
The main functional control of the DSP is through
two hardware registers which are accessible at any
time via the microport. These are the Receive Gain
Control Register at address 1Dh and the DSP
Control Register at address 1Eh. In addition, other
functional control is accomplished via multiple RAMbased registers which are accessible only while the
DSP is held in a reset state. This is accomplished
with the DRESET bit of the DSP Control Register.
Ram-based registers are used to store transmit gain
levels (20h for transmit PCM and 21h for transmit
DTMF levels), the coefficients for tone and ringer
generation (addresses 23h and 24h), and tone ringer
warble rates (address 26h). All undefined addresses
below 20h are reserved for the temporary storage of
interim variables calculated during the execution of
the DSP algorithms. These undefined addresses
should not be written to via the microprocessor port.
The DSP can be programmed to execute the
following micro-programs which are stored in
instruction ROM, (see PS0 to PS2, DSP Control
Register, address 1Eh). All program execution
begins at the frame pulse boundary.
PS2
PS1
PS0
Micro-program
0
0
0
Power up reset program
0
0
1
Transmit and receive gain control
program; with autonulling of the
transmit PCM, if the AUTO bit is
set (see address 1Dh)
0
1
0
DTMF generation plus transmit
and
receive
gain
control
program (autonull available via
the AUTO control bit)
0
1
1
Tone ringer plus transmit and
receive gain control program
(autonull available via the
AUTO control bit)
MT9092
PS2
1
1
PS1
PS0
0
0
0
1
1
1
0
1
1
1
Note:
Micro-program
Optional Offset Nulling
handsfree switching program
Last three selections reserved
For the DSP to function it must be selected to
operate, in conjunction with the Filter/Codec, in
one of the B-Channels. Therefore, one of the BChannel enable bits must be set (see Timing
Control, address 15h : bits CH2EN and CH 3EN).
Power Up reset Program
A hardware power-up reset (pin 6, PWRST) will
initialize the DSP hardware registers to the default
values (all zeros) and will reset the DSP program
counter. The DSP will then be disabled and the PCM
streams will pass transparently through the DSP. The
RAM-based registers are not reset by the PWRST
pin but may be initialized to their default settings by
programming the DSP to execute the power up reset
program. None of the micro-programs actually
require the execution of the power up reset program
but it is useful for pre-setting the variables to a
known condition. Note that the reset program
requires one full frame (125µSec) for execution.
Gain Control Program
Gain control is performed on converted linear code
for both the receive and the transmit PCM. Receive
gain control is set via the hardware register at
address 1Dh (see bits B0 - B5) and may be changed
at any time. Gain in 1.5dB increments is available
within a range of +22.5dB to -72dB. Normal
operation usually requires no more than a +20 to -20
dB range of control. However, the handsfree
switching algorithm requires a large attenuation
depth to maintain stability in worst case
environments, hence the large (-72 dB) negative
limit. Transmit gain control is divided into two RAM
registers, one for setting the network level of transmit
speech (address 20h) and the other for setting the
transmit level of DTMF tones into the network
(address 21h). Both registers provide gain control in
1.5dB increments and are encoded in the same
manner as the receive gain control register (see
address 1Dh, bits B0 - B5). The power up reset
program sets the default values such that the receive
gain is set to -72.0 dB, the transmit audio gain is set
to 0.0dB and the transmit DTMF gain is set to -3.0
dB (equivalent to a DTMF output level of -4dBm0 into
the network).
Transmit PCM may contain residual offset in the form
of a DC component. An offset of up to ±fifteen linear
bits is acceptable with no degradation of the
parameters defined in CCITT G.714. The HPhone-II
filter/CODEC guarantees no more than ±ten linear
bits of offset in the transmit PCM when the autonull
routine is not enabled. By enabling autonulling (see
AUTO in the Receive Gain Control Register, address
1Dh) offsets are reduced to within ±one bit of zero.
Autonulling circuitry was essential in the first
generations of Filter/Codecs to remove the large DC
offsets found in the linear technology. Newer
technology has made nulling circuitry optional as
offered in the HPhone-II.
DTMF and Gain Control Program
The DTMF program generates a dual cosine wave
pattern which may be routed into the receive path as
comfort tones or into the transmit path as network
signalling. In both cases, the digitally generated
signal will undergo gain adjustment as programmed
into the Receive Gain Control and the Transmit
DTMF Gain Control registers. The composite signal
output level in both directions is -4dBm0 when the
gain controls are set to 2Eh (-3.0 dB). Adjustments to
these levels may be made by altering the settings of
the gain control registers. Pre-twist of 2.0dB is
incorporated into the composite signal. The
frequency of the low group tone is programmed by
writing an 8-bit coefficient into Tone Coefficient
Register 1 (address 23h), while the high group tone
frequency uses the 8-bit coefficient programmed into
Tone Coefficient Register 2 (address 24h). Both
coefficients are determined by the following
equation:
COEFF = 0.128 x Frequency (in Hz)
where COEFF is a rounded off 8 bit binary integer
A single frequency tone may be generated instead of
a dual tone by programming the coefficient at
address 23h to a value of zero. In this case the
frequency of the single output tone is governed by
the coefficient stored at address 24h.
7-9
MT9092
Table 1 gives the standard DTMF frequencies, the
coefficient required to generate the closest
frequency, the actual frequency generated and the
percent deviation of the generated tone from the
nominal.
Frequency
(Hz)
COEF
Actual
Frequency
%
Deviation
697
59h
695.3
-.20%
770
63h
773.4
+.40%
852
6Dh
851.6
-.05%
941
79h
945.3
+.46%
1209
9Bh
1210.9
+.20%
1336
ABh
1335.9
.00%
1477
BDh
1476.6
-.03%
1633
D1h
1632.8
-.01%
Table 1
DTMF Signal to distortion:
The sum of harmonic and noise power in the
frequency band from 50Hz to 3500Hz is typically
more than 30dB below the power in the tone pair. All
individual harmonics are typically more than 40dB
below the level of the low group tone.
Tone Ringer and Gain Control Program
A locally generated alerting (ringing) signal is used to
prompt the user when an incoming call must be
answered. The DSP uses the values programmed
into Tone Coefficient Registers 1 and 2 (addresses
23h and 24h) to generate two different squarewave
frequencies in PCM code. The amplitude of the
squarewave frequencies is set to a mid level before
being sent to the receive gain control block. From
there the PCM passes through the decoder and
receive filter, replacing the normal receive PCM data,
on its way to the loudspeaker driver. Both
coefficients are determined by the following
equation:
COEFF = 8000/Frequency (Hz)
where COEFF is a rounded off 8 bit binary integer.
The ringer program switches between these two
frequencies at a rate defined by the 8-bit coefficient
programmed into the Tone Ringer Warble Rate
Register (address 26h). The warble rate is defined
by the equation:
Tone duration (warble frequency
in Hz) = 500/COEFF
where 0 < COEFF < 256, a warble rate of 5-20Hz is
suggested.
7-10
An alternate method of generating ringer tones to the
speakerphone speaker is available. With this method
the normal receive speech path through the decoder
and receive filter is uninterrupted to the handset,
allowing an existing conversation to continue. The
normal DSP and Filter/CODEC receive gain control
is also retained by the speech path. When the OPT
bit (DSP Control Register address 1Eh) is set high
the DSP will generate the new call tone according to
the coefficients programmed into registers 23h, 24h
and 26h as before. In this mode the DSP output is no
longer a PCM code but a toggling signal which is
routed directly through the New Call Tone gain
control section to the loudspeaker driver. Refer to
the section titled ‘New Call Tone’.
Handsfree Program
A half-duplex speakerphone program, fully contained
on chip, provides high quality gain switching of the
transmit and receive speech PCM to maintain loop
stability under most network and local acoustic
environments. Gain switching is performed in
continuous 1.5dB increments and operates in a
complimentary fashion. That is, with the transmit
path at maximum gain the receive path is fully
attenuated and vice versa. This implies that there is
a mid position where both transmit and receive paths
are attenuated equally during transition. This is
known as the idle state.
Of the 64 possible attenuator states, the algorithm
may rest in only one of three stable states; full
receive, full transmit and idle. The maximum gain
values for full transmit and full receive are
programmable through the microport at addresses
20h and 1Dh respectively, as is done for normal
handset operation. This allows the user to set the
maximum volumes to which the algorithm will
adhere. The algorithm determines which path should
maintain control of the loop based upon the relative
levels of the transmit and receive audio signals after
the detection and removal of background noise
energy. If the algorithm determines that neither the
transmit or the receive path has valid speech energy
then the idle state will be sought. The present state
of the algorithm plus the result of the Tx vs. Rx
decision will determine which transition the algorithm
will take toward its next stable state. The time
durations required to move from one stable state to
the next are parameters defined in CCITT
Recommendation P.34 and are used by default by
this algorithm (i.e., build-up time, hang-over time and
switching time).
MT9092
Quiet Code
The DSP can be made to send quiet code to the
decoder and receive filter path by setting the
RxMUTE bit high. Likewise, the DSP will send quiet
code in the transmit (DSTo) path when the TxMUTE
bit is high. Both of these control bits reside in the
DSP Control Register at address 1Eh. When either
of these bits are low, their respective paths function
normally.
HDLC
The High-level Data Link Control (HDLC) block is
located, functionally, between the serial ST-BUS port
and the serial Microcontroller port. This functional
block handles the bit oriented protocol requirements
of layer 2 X.25 packet switching and Q.921 link
access protocols defined by CCITT. The HDLC is
dedicated to D-Channel operation at 16kb/s and
offers buffered access to the serial D-Channel data
through separate 19 byte transmit and receive
FIFOs.
The HDLC generates and detects the flags, various
link channel states and abort sequences as well as
performing a cyclic redundancy check on data
packets according to the CCITT defined polynomial.
Lastly, the protocol functions may be disabled to
provide transparent access, of the serial port DChannel, to the microport.
A power up reset (PWRST, pin 6) or a software reset
via RST (address 0Fh) will cause the HDLC
transceiver to be initialized. This results in the
transmitter and receiver being disabled and all HDLC
registers defaulting to their power reset values.
HDLC Frame Structure
A valid HDLC frame begins with an opening flag,
contains at least 16 bits of address, control or
information, ends with a 16 bit FCS followed by a
closing flag. Data formatted in this manner is also
referred to as a "packet". Refer to Figure 4.
FLAG
DATA FIELD
FCS
FLAG
One
Byte
n Bytes
(n≥2)
Two
Bytes
One
Byte
Figure 4 - Frame Format
Flag Sequence
All HDLC frames start and end with a unique
sequence of 8 bits. This sequence is 0111 1110
(7Eh). The closing flag of one frame can be the
opening flag of the next frame. The transmitter
generates flags and appends them to the packet to
be transmitted. The receiver searches the incoming
data stream for flags on a bit-by-bit basis to establish
frame synchronization. The receiver uses flags for
synchronization only and does not transfer them to
the Rx FIFO.
Address Field
The address field consists of one or two 8-bit bytes
directly following the opening flag. Address, Control
and Information fields are known collectively as the
Data field.
Control Field
The control field consists of one 8-bit byte directly
following the address field. The HDLC does not
distinguish between the control field and the
information field.
Information Field
The information field immediately follows the control
field and consists of N bytes of data where one byte
contains 8 bits. A packet does not need to contain an
information field to be valid. The HDLC does not
distinguish between the control field and the
information field.
Frame Checking Sequence Field
The 16 bits preceding a closing flag are the FCS
field. A cyclic redundancy check utilizing the CRCCCITT standard generator polynomial X 16 + X12 +X5
+1 produces the 16-bit FCS. In the transmitter the
FCS is calculated on all bits of the address, control
and information fields. The complement of the FCS
is transmitted, most significant bit first, in the FCS
field. The receiver calculates the FCS on the
incoming packet's address, control, information and
FCS fields and compares the result to 'F0B8'. This
result verifies no transmission errors occurred. If the
packet, between flags, is also at least 32 bits in
length then the address, control and information field
data are entered into the receive FIFO minus the
FCS which is discarded.
Order of Bit Transmission
Address, control and information field data are
entered into the transmit FIFO. This data is then
transmitted and received on the serial bus least
significant bit first. The FCS is sent most significant
bit first on the serial bus. Note that it is the
complement of the calculated FCS which is
transmitted. The HDLC does not distinguish
ADDRESS/CONTROL/INFORMATION bytes except
7-11
MT9092
to determine if the packet is of minimum valid length.
These fields are transferred transparently through
the FIFO's.
transmitted packet. If this happens, then the last data
written to the receive FIFO will not correspond
exactly with the last byte received before the frame
abort.
Data Transparency (Zero insertion/deletion)
Interframe Time Fill and Link Channel States
Transparency ensures that the contents of a data
packet do not imitate a flag, go-ahead, frame abort
or idle channel. The contents of a transmitted frame,
between the flags, is examined on a bit-by-bit basis
and a 0 bit is inserted after all sequences of five
contiguous 1 bits (including the last five bits of the
FCS). Upon receiving five contiguous 1s within a
frame the receiver deletes the following 0 bit.
When the HDLC transmitter is not sending packets it
will wait in one of two states.
Interframe Time Fill: This is a continuous series of
flags
occurring
between
frames indicating that the
channel is active but that no
data is being sent.
Invalid Frames
A frame is invalid if one of the following four
conditions exists. Inserted zeros are not part of a
valid bit count:
1. If the FCS pattern generated from the received
data does not match the 'F0B8' pattern then the
last data byte of the packet is written to the
receive FIFO with a 'bad packet' indication.
2. A short frame exists if there are less than 25 bits
between the flags. Short frames are ignored by
the receiver and nothing is written into the
receive FIFO.
3. Packets which are at least 25 bits in length but
less than 32 bits (between the flags) are also
invalid. In this case the data is written to the
FIFO but the last byte is tagged with a 'bad
packet' indication.
4. If a frame abort sequence is detected the packet
is invalid. Some or all of the current packet will
reside in the receive FIFO, assuming the packet
length before the abort sequence was at least 26
bits long.
Idle:
An idle channel occurs when at least fifteen
contiguous 1s are transmitted or received.
In both cases the transmitter will exit the wait state
when data is loaded into the transmit FIFO.
Go-Ahead
A go-ahead is defined as the pattern ‘011111110’
(contiguous 7F’s) and is the occurrence of a frame
abort sequence followed by a zero, outside of the
boundaries of a normal packet. Being able to
distinguish a proper (in packet) frame abort
sequence from one occurring outside of a packet
allows a higher level of signalling protocol which is
not part of the HDLC specifications.
Transmitter
Following initialization and enabling, via the HTxEN
bit (address 03h), the transmitter is in the Idle
Channel State (Mark Idle). Interframe time fill may
be selected by setting the Mark Idle bit (address 03h)
high. The transmitter remains in its programmed
state until data is written to the Tx FIFO. The
transmitter will then proceed as follows:
Frame Abort
The transmitter will abort a current packet by
substituting a zero followed by seven contiguous 1s
in place of the normal data. The receiver will abort
upon reception of seven contiguous 1s occurring
between the flags of a packet which contains at least
26 bits.
Note that should the last receive byte before the
frame abort end with contiguous 1s, these are
included in the seven 1s required for a receiver
abort. This means that the location of the abort
sequence in the receiver may occur before the
location of the abort sequence in the originally
7-12
1)
If the transmitter is in the idle state the present
byte of ones will be completely transmitted
before the opening flag and packet data is
sent.
2)
If the transmitter is in the interframe time fill
state the flag currently being transmitted will be
used as the opening flag followed by the
packet data.
To assist in loading multiple packets into the transmit
FIFO the last packet byte is tagged with either EOP
(to indicate the end of the current packet) or FA.
Control Register 1 (address 03h) bits EOP (end of
MT9092
packet) and FA (frame abort) are set before writing
the last packet byte to the Tx FIFO. The act of
loading the last packet byte will then automatically
reset the EOP and FA bits. Tx FIFO bytes are
continuously transmitted until the FIFO is empty, by
which time an EOP or FA tag should have been
encountered by the transmitter.
After the last bit of the EOP byte has been
transmitted a 16 bit FCS is sent followed by a closing
flag. When multiple packets of data are loaded into
the Tx FIFO only one flag is sent between packets.
When the transmitter encounters a byte tagged FA
then a frame abort sequence is sent instead of the
tagged byte. All bytes previous to but not including
the tagged byte are sent.
Command/Address byte which indicates a microport
read of address 07h. Since all interrupts are
generated by the occurrence of an HDLC event (i.e.,
a transition), this register informs that an event has
occurred but does not guarantee that it is still valid.
To determine current validity the HDLC Status
Register (address 04h) should be read. Due to the
asynchronous nature of the interrupts an interrupt
occurring during a read of the Interrupt Status
register will be held until the read cycle is over,
unless it is an interrupt which is already valid.
There are three interrupts associated with the
transmitter.
TEOP
Transmit End Of Packet:
Set when the transmitter has finished
sending the closing flag of a packet or
after an abort sequence has been
completed.
TxFL
Transmit FIFO Low:
Set when a transition from 5 to 4 bytes
in the Tx FIFO has occurred. This is an
early warning to the microprocessor
that the FIFO is emptying and should
be serviced before it empties
completely; a condition which will
result in a transmit underrun unless an
EOP or FA byte has been written to the
FIFO. By setting the Fltx bit (address
05h) high the FIFO emptying condition
will occur at the transition from 15 to 14
bytes. This will allow the microport
more time to react to this interrupt
condition.
The transmitter returns to its programmed wait state
after concluding the transmission of EOP or FA if the
Tx FIFO is empty.
Transmit FIFO Status
The transmit FIFO is 19 bytes deep (address 02h).
As data is loaded into (from the microport) and
extracted from (via the serial port) the Tx FIFO the
present 'fill state' can be monitored using the Txstat1
and Txstat2 bits found in the HDLC Status Register
(address 04h). These states are encoded as shown
in Table 2. Note that the FIFO emptying threshold,
where an interrupt (TxFL if unmasked) will occur, can
be set to a low level 4 (default) or to a high level 14
by the Fltx bit in the HDLC Control Register 2
(address 05h).
A Tx FIFO underrun occurs if the Tx FIFO empties
without the occurrence of an EOP or FA tagged byte.
A frame abort sequence is automatically transmitted
under this condition.
Transmit Interrupts
The HDLC Interrupt Enable Register (address 06h)
is used to select (unmask) only those interrupts
which are deemed important to the microprocessor.
After a PWRST or software RST all enable bits will
be cleared causing all interrupts to be masked.
All selected interrupt events will cause the IRQ pin to
become active. Unselected interrupt events will not
cause IRQ to become active however, the event will
still be represented by the appropriate bit in the
HDLC Interrupt Status Register (address 07h). This
register must be read after receiving an IRQ or may
be polled at any time. The IRQ output pin is reset
coincident with the first SCLK falling edge following a
Txunder Transmit underrun:
Set when the Tx FIFO empties without
the occurrence of an EOP or FA
tagged byte. A frame abort sequence
is automatically transmitted under this
condition. Note that this register bit
position is shared with the frame abort
(FA) interrupt (see receive interrupts).
For this bit to reflect Txunder the Intsel
bit in Control Register 2 (address 05h)
must be set high.
Disabling, Reset, Transparent Operation and CRC
Disabling the transmitter via the HTxEn bit will occur
after the current packet is completely transmitted.
The status and Interrupt registers may still be read
and the Tx FIFO and control registers written while
the transmitter is disabled.
7-13
MT9092
The Tx FIFO may be reset by setting the Txfrst bit in
the HDLC Control Register 2 (address 05h). The
HDLC Status Register will identify the Tx FIFO as
being empty although the actual data in the FIFO will
not be reset. Txfrst will be cleared by the next write
to the Tx FIFO.
Transparent data may be sent by setting the TRANS
bit (address 03h) high. The transmitter will no longer
generate the flag, abort and idle sequences, nor will
it insert zeros and append the FCS. Data will still be
transmitted LSB first. If there is no data in the Tx
FIFO or the Tx FIFO empties the last byte
transmitted will be repetitively sent until new data is
presented to the FIFO. It will take typically two STBUS frames, after writing TRANS, before this mode
begins. Note that CH 0EN must also be set.
Transmission of the FCS field CRC may be inhibited
using the Tcrci (Transmit Crc Inhibit) bit at address
05h. While this bit is set the opening flag followed by
the data fields and closing flag is transmitted,
including zero insertion, but the calculated CRC is
not. This allows the processor to insert the CRC as
part of the data field. This usage is for V.120 terminal
adaptation for synchronous protocol sensitive UI
frames.
If address recognition is required, Receive Address
Recognition Registers 1 and/or 2 (addresses 00h
and 01h respectively) are loaded with the desired
address comparison information, the Adrec bit is set
high and A1EN and A2EN are set as required. Bit 0
(A1EN and A2EN) of both recognition registers is
used as an enable for that byte. When either of these
bits are low their respective address mask
information is ignored. In this way either or both of
the first two received bytes can be compared to the
expected mask values. Only those packets passing
the appropriate comparison test will be loaded into
the Rx FIFO. The appropriate comparison test
(single/dual byte address, All-call) is defined by the
logic state of bit 0 of the first byte received after the
opening flag.
Bit 0 of the first received address byte (address
extension bit) is monitored to determine if a single or
dual byte address is being received.
1.
If the address extension bit is 1 then a single
byte address is being received. If A1EN is high
the stored bit mask (Adr11 - Adr16 and
sometimes Adr10) is compared to the received
first address byte. Any packet failing this
address comparison will not be stored in the Rx
FIFO except for the All-call condition. A1EN
must be set high for a single-byte All-call
(11111111) address to be recognized. The
second mask byte is ignored. Seven bits of
address comparison may be realized for single
byte recognition by setting the SEVEN bit
(address 05h) high. This mode will then include
Adr10 as part of the mask information. The first
received byte must also have bit 0 set to a 1
indicating single byte addressing.
2.
If the address extension bit is 0 then a two byte
address is being received and the six most
significant bits of the first received byte are
compared. The seven most significant bits of the
second received byte are compared (Adr20 Adr26, note A2EN must be set high also). Any
packet failing this address comparison will not
be stored in the Rx FIFO. An All-call condition
(1111111x) is also monitored for in the second
received address byte and, if found, the first and
second byte masks are ignored (not compared
with the mask byte). Packets addressed with Allcall are written into the Rx FIFO.
Receiver
Following initialization and enabling, via the HRxEN
bit at address 03h, the receiver begins clocking in
serial data checking for flags (0111 1110), go-aheads
(0111 1111 0), and idle channel states (at least fifteen
contiguous ones). Upon detecting a flag the receiver
synchronizes itself to the data stream and begins
calculating the CRC. If the packet length, between
the flags and after zero deletion, is less than 25 bits
the packet is ignored and nothing is written to the Rx
FIFO. If the packet length, after zero deletion, is
between 25 and 31 bits a last byte, bad packet
indication is written into the Rx FIFO.
Idle Channel
When the receiver detects at least 15 contiguous
ones it declares an idle channel condition exists and
sets the IdleChan bit in the HDLC status register
high (address 04h). This bit remains set until the
received condition changes.
Address Recognition
When Adrec (HDLC Control Register 1, address
03h) is low all valid received packets, regardless of
the address field information, are loaded into the Rx
FIFO.
7-14
In CCITT Q.921 parlance the Adr11 - Adr16 bits are
defined as Sapi0 - Sapi5 (Service Access Point
Identifier n). Adr10 is defined as C/R (Command/
Response). Adr20 - Adr26 are defined as Tei0 - Tei6
(Terminal Endpoint Identifier n).
MT9092
Receive Byte Status
As each received packet byte is written into the Rx
FIFO two bits are appended to indicate the status of
that byte. As these bytes are read from the Rx FIFO
the status bits are made available to the
microprocessor in the HDLC Status Register
(address 04h) as RxBS1 and RxBS2. Since the
information contained in RxBS1 & RxBS2 pertains to
the byte about to be read from the Rx FIFO, it is
important that this information be read before
reading the data byte from the FIFO. RxBS1 and
RxBS2 are encoded as shown in Table 2. A good
packet indication means a good FCS and no frame
abort whereas a bad packet indication means either
an incorrect FCS or a frame abort occurred.
in Table 2. Note that the FIFO filling threshold, where
an interrupt (RxFf if unmasked) will occur, can be set
to a high level 15 (default) or to a low level 5 by the
Flrx bit in the HDLC Control Register 2 (address
05h).
In the case of an Rx FIFO overflow, an attempt by
the receiver to write data into an already full FIFO,
the receiver is disabled causing it to stop writing to
the Rx FIFO. The remainder of the current receive
packet is therefore ignored. The receiver will be reenabled when the next flag is detected but will
overflow again if the Rx FIFO level has not been
reduced to less than full. If two 'first byte' (RxBS1
and RxBS2) conditions are observed in the FIFO
without an intervening 'last byte' then an overflow
occurred for the first packet.
Receive FIFO Status
Receive Interrupts
The receive FIFO is 19 bytes deep (address 02h). As
data is loaded into (from the serial port) and
extracted from (via the microport) the Rx FIFO the
present 'fill state' can be monitored using the Rxstat1
and Rxstat2 bits found in the HDLC Status Register
(address 04h). These states are encoded as shown
RxBS2,
RxBS1
Note
-
Txstat2,
Txstat1
Rxstat2,
Rxstat1
The HDLC Interrupt Enable Register (address 06h)
is used to select (unmask) only those interrupts
which are deemed important to the microprocessor.
After a PWRST or software RST all enable bits will
be cleared causing all interrupts to be masked.
Are status bits from the Rx FIFO.
RxBS1
Byte status
RxBS2
1
1
last byte (bad packet)
0
1
first byte
1
0
last byte (good packet)
0
0
packet byte
If two consecutive first byte signals are received without an intervening last byte, then an
overflow has occurred and the first packet (or packets) are bad. A bad packet indicates that
either a frame abort had occurred or the FCS did not match.
On power-up these bits are in an indeterminate state until the first byte is written to Rx FIFO.
These two bits are encoded to indicate the present state of Tx FIFO. This is an asynchronous
event.
Txstat2
Txstat1
Tx FIFO Status
0
0
TxFULL
0
1
5 OR MORE BYTES (15 if Fltx set)
1
1
4 OR LESS BYTES (14 if Fltx set)
1
0
TxEMPTY
These two bits are encoded to indicate the present state of Rx FIFO. This is an asynchronous
event.
Rxstat2
Rxstat1
Rx FIFO Status
0
0
RxEMPTY
0
1
14 OR LESS BYTES (4 if Flrx set)
1
1
15 OR MORE BYTES (5 if Flrx set)
1
0
RxOVERFLOW EXISTS
Table 2 - HDLC Status Bits
7-15
MT9092
All selected interrupt events will cause the IRQ pin to
become active. Unselected interrupt events will not
cause IRQ to become active however, the event will
still be represented by the appropriate bit in the
HDLC Interrupt Status Register (address 07h). This
register must be read after receiving an IRQ or may
be polled at any time. The IRQ output pin is reset
coincident with the first SCLK falling edge following a
Command/Address byte which indicates a microport
read of address 07h. Since all interrupts are
generated by the occurrence of an HDLC event (i.e.,
a transition), this register informs that an event has
occurred but does not guarantee that it is still valid.
To determine current validity the HDLC Status
Register (address 04h) should be read. Due to the
asynchronous nature of the interrupts an interrupt
occurring during a read of the Interrupt Status
register will be held until the read cycle is over,
unless it is an interrupt which is already valid.
There are six interrupts associated with the receiver.
GA
Go Ahead:
Set when a go-ahead pattern
(011111110) has been detected by the
receiver.
EOPD
End Of Packet Detect:
Set when an end of packet byte has
been written into the Rx FIFO by the
receiver. This event may be due to
receiving a closing flag, an abort
sequence or an invalid packet.
EopR
End of packet Read:
Set when the next byte to be read from
the Rx FIFO is the last byte of a
packet or when a read to an empty Rx
FIFO has occurred.
FA
Frame Abort:
Set when a frame abort sequence is
received during packet reception. The
aborted packet must contain a
minimum of 26 bits for the FA
sequence to be recognized. Note that
this register bit position is shared with
the transmitter under-run (Txunder)
interrupt (see transmit interrupts). For
this bit to reflect FA the Intsel bit in
Control Register 2 (address 05h) must
be set low.
RxFf - Receive FIFO filling:
Set when a transition from 14 to 15
bytes in the Rx FIFO has occurred.
This is an early warning to the
microprocessor that the FIFO is filling
and should be serviced before it
7-16
becomes completely full; a condition
which may result in a receive overflow
condition. By setting the Flrx bit
(address 05h) high the FIFO filling
condition will occur when a transition
from 4 to 5 bytes occurs. This will
allow the microport more time to react
to this interrupt condition.
RxOvfl - Receive FIFO Overflow:
Set when the receiver attempts to
write data into an already full Rx FIFO.
Under this condition the HDLC will
disable the receiver until a new flag is
detected. See also Receive FIFO
Status.
Disabling, Reset and Transparent Operation
Disabling of the receiver via the HRxEn bit will occur
after the current packet is completely loaded into the
Rx FIFO. Disabling can occur during packet
reception if no bytes have been written to the Rx
FIFO yet. The Rx FIFO, status and Interrupt registers
may still be read and control registers written while
the receiver is disabled. Note that the receiver
requires the reception of a flag before processing a
packet, thus if the receiver is enabled in the middle
of an incoming packet it will ignore that packet and
wait for the next complete one.
The Rx FIFO may be reset by setting the Rxfrst bit in
the HDLC Control Register 2 (address 05h). The
receiver will be disabled until reception of the next
flag. The Status Register will identify the Rx FIFO as
being empty although the actual data in the FIFO will
not be reset. Rxfrst will be cleared by the reception
of the next received flag pattern.
Data may be received transparently by setting the
TRANS bit (address 03h) high. Timing control bit
CH 0EN must also be set. The receiver will disable
protocol functions such as flag/abort/go-ahead/idle
detection, zero deletion, CRC calculation and
address comparison. Data is shifted into the Rx FIFO
in a byte-wide format. In transparent mode when an
Rx FIFO overflow condition occurs the receiver will
continue to write data into the Rx FIFO, overwriting
the last byte. The overflow interrupt condition can
only be detected again if the Rx FIFO is reset (Rxfrst
bit at address 05h) since normally the overflow
condition is cleared by the reception of the next flag
and transparent data is unlikely to emulate a flag.
Also, the Rxfrst bit itself will have to be reset by
writing it low since it is usually reset automatically by
the occurrence of the next flag.
MT9092
Transducer Interfaces
HSPKR+
Four standard telephony transducer interfaces are
provided by the HPhone-II. These are:
75 Ω
➧
➧
➧
The handset microphone inputs (transmitter),
pins M+/M- and the speakerphone microphone
inputs, pins MIC+/MIC-. The transmit path is
muted/not-muted by the MIC EN control bit.
Selection of which input pair is to be routed to
the transmit filter amplifier is acomplished by the
MIC/HNSTMIC control bit. Both of these reside
in the Transducer Control Register (address
0Eh). The nominal transmit path gain may be
adjusted to either 6.1dB (suggested for µ-Law)
or 15.4dB (suggested for A-Law). Control of this
gain is provided by the MICA/u control bit
(General Control Register, address 0Fh). This
gain adjustment is in addition to the
programmable gain provided by the transmit
filter and DSP.
The handset speaker outputs (receiver), pins
HSPKR+/HSPKR-.
This
internally
compensated, fully differential output driver is
capable of driving the load shown in Figure 5.
This output is enabled/disabled by the HSSPKR
EN bit residing in the Transducer Control
Register (address 0Eh). The nominal handset
receive path gain may be adjusted to either
-12.3dB (suggested for µ-Law) or -9.7dB
(suggested for A-Law). Control of this gain is
provided by the RxA/u control bit (General
Control Register, address 0Fh). This gain
adjustment is in addition to the programmable
gain provided by the receive filter and DSP.
The loudspeaker outputs, pins SPKR+/SPKR-.
This internally compensated, fully differential
output driver is capable of directly driving 6.5vpp
into a 40 ohm load. This output is enabled/
disabled by the SPKR EN bit residing in the
Transducer Control Register (address 0Eh). The
nominal gain for this amplifier is 0.2dB.
1000 pF
150 ohm
load
MT9092
(speaker)
75 Ω
1000 pF
HSPKR-
ground
Figure 5- Handset Speaker Driver
LCD
A twelve segment, non-multiplexed, LCD display
controller is provided for easy implementation of
various set status and call progress indicators. The
twelve output pins (Sn) are used in conjunction with
12 segment control bits, located in LCD Segment
Enable Registers 1&2 (addresses 12h and 13h), and
the BackPlane output pin (BP) to control the on/off
state of each segment individually.
The BP pin drives a continuous 62.5Hz, 50% duty
cycle squarewave output signal. An individual
segment is controlled via the phase relationship of its
segment driver output pin with respect to the
backplane, or common, driver output. Each of the
twelve Segment Enable bits corresponds to a
segment output pin. The waveform at each segment
pin is in-phase with the BP waveform when its
control bit is set to logic zero (segment off) and is
out-of-phase with the BP waveform when its control
bit is set to a logic high (segment on). Refer to the
LCD Driver Characteristics for pin loading
information.
C-Channel
Microport
Access to the internal control and status registers of
Mitel basic rate, layer 1, transceivers is through the
ST-BUS Control Channel (C-Channel), since direct
microport access is not usually provided, except in
the case of the SNIC (MT8930). The HPhone-II
provides asynchronous microport access to the STBUS C-Channel information on both DSTo and DSTi
via a double-buffered read/write register (address
14h). Data written to this address is transmitted on
the C-Channel every frame when enabled by CH 1EN
(see ST-BUS/Timing Control).
A serial microport, compatible with Intel MCS-51
(mode 0) specifications, provides access to all
HPhone-II internal read and write registers. This
microport consists of three pins; a half-duplex
transmit/receive data pin (DATA1), a chip select pin
(CS) and a synchronous data clock pin (SCLK).
On power-up reset (PWRST) or with a software reset
(RST), the DATA1 pin becomes a bidirectional
(transmit/receive) serial port while the DATA2 pin is
internally disconnected and tri-stated.
7-17
MT9092
All data transfers through the microport are two-byte
transfers requiring the transmission of a Command/
Address byte followed by the data byte written or
read from the addressed register. CS must remain
asserted for the duration of this two-byte transfer. As
shown in Figure 6, the falling edge of CS indicates to
the HPhone-II that a microport transfer is about to
begin. The first 8 clock cycles of SCLK after the
falling edge of CS are always used to receive the
Command/Address byte from the microcontroller.
The Command/Address byte contains information
detailing whether the second byte transfer will be a
read or a write operation and of what address. The
next 8 clock cycles are used to transfer the data byte
between the HPhone-II and the microcontroller. At
the end of the two-byte transfer CS is brought high
again to terminate the session. The rising edge of CS
will tri-state the output driver of DATA1 which will
remain tri-stated as long as CS is high.
Lastly, provision is made to seperate the transmit
and receive data streams onto two individual pins.
This control is given by the DATASEL pin in the
General Control Register (address 0Fh). Setting
DATASEL logic high will cause DATA1 to become the
data receive pin and DATA2 to become the data
transmit pin. Only the signal paths are altered by
DATASEL; internal timing remains the same in both
cases. Tri-stating on DATA2 follows CS as it does on
DATA1 when DATASEL is logic low. Use of the
DATASEL bit is intended to help in adapting Motorola
(SPI) and National Semiconductor (Micro-wire)
microcontrollers to the HPhone-II. Note that whereas
Intel processor serial ports transmit data LSB first
other processor serial ports, including Motorola,
transmit data MSB first. It is the responsibility of the
microcontroller to provide LSB first data to the
HPhone-II.
ST-BUS/Timing Control
Receive data is sampled and transmit data is made
available on DATA1 concurrent with the falling edge
of SCLK.
An open-drain interrupt request (IRQ) output
provides
a
method
for
interrupting
the
microcontroller when an unmasked HDLC event
occurs within the HPhone-II. IRQ remains active until
the HDLC Interrupt Status Register is read or a
(hardware/software) reset occurs. More detail is
provided in the section pertaining to the HDLC
functional block.
COMMAND/ADDRESS ➄
DATA 1
Receive
D0 D1 D2 D3 D4 D5 D6 D7
DATA 1 or DATA 2
Transmit
➀
A serial link is required for the transport of data
between the HPhone-II and the external digital
transmission device. The HPhone-II utilizes the STBUS architecture defined by Mitel Semiconductor.
Refer to Mitel Application Note MSAN-126. The
HPhone-II ST-BUS consists of output and input
serial data streams, DSTo and DSTi respectively, a
synchronous clock signal C4i, and a framing pulse
F0i.
DATA INPUT/OUTPUT
➃ COMMAND/ADDRESS
➀
D0 D1 D2 D3 D4 D5 D6 D7
D0 D1 D2 D3 D4 D5 D6 D7
D0 D1 D2 D3 D4 D5 D6 D7
D0 D1 D2 D3 D4 D5 D6 D7
SCLK ➁
➃
CS
➂
➂
➀
➁
Delays due to MCS-51 internal timing which are transparent.
➂
The falling edge of CS indicates that a COMMAND/ADDRESS byte will be transmitted from the microprocessor. The subsequent
byte is always data followed by CS returning high.
➃
A new COMMAND/ADDRESS byte may be loaded only by CS cycling high then low again.
D7
The COMMAND/ADDRESS byte contains:
1 bit - Read/Write
0
A5
A4
6 bits - Addressing Data
1 bit - Not used, write logic "0"
➄
The HPhone-II: -latches received data on the falling edge of SCLK
-outputs transmit data on the falling edge of SCLK
Figure 6 - Serial Port Relative Timing
7-18
D0
A3
A2
A1
A0
R/W
MT9092
The data streams operate at 2048kb/s and are Time
Division Multiplexed into 32 identical channels of
64kb/s bandwidth. Frame Pulse (a 244nSec low
going pulse) is used to parse the continuous serial
data streams into the 32 channel TDM frames. Each
frame has a 125µSecond period translating into an 8
kHz frame rate. Valid frame pulse occurs when F0i is
logic low coincident with a falling edge of C4i. C4i
has a frequency (4096MHz) which is twice the data
rate. This clock is used to sample the data at the 3/4
bit-cell position on DSTi and to make data available
on DSTo at the start of the bit-cell. C4i is also used
to clock the HPhone-II internal functions (i.e., DSP,
Filter/CODEC, HDLC) and to provide the channel
timing requirements.
The HPhone-II uses only the first 4 channels of the
32 channel frame. These channels are always
defined, beginning with the first channel after frame
pulse, as shown in Figure 7 (DSTi and DSTo channel
assignments). Channels are enabled independantly
by the four control bits Ch0En -Ch 3En residing in the
Timing Control Register (address15h).
Ch0EN - D-Channel
Channel 0 conveys the D-Channel HDLC
information. Since this function is dedicated to
16kb/s operation, only the first two bits (LSB's)
of the octet are required; the remaining six bits
of the D-Channel octet carry no information and
are tri-stated. When CH 0EN is high, HDLC data
is transmitted on DSTo. When low, DSTo is
forced to logic 0 for the two least significant bit
positions.
Incoming DSTi data is always
routed to the HDLC block regardless of this
control bit's logic state.
Ch1EN - C-Channel
Channel
1
conveys
the
control/status
information for Mitel’s layer 1 transceiver. The
full 64kb/s bandwidth is available and is
assigned according to which transceiver is
being used. Consult the data sheet for the
selected transceiver for its bit definitions and
order of bit transfer. When this bit is high
register data is transmitted on DSTo. When low,
this timeslot is tri-stated on DSTo. Receive CChannel data (DSTi) is always routed to the
register regardless of this control bit's logic
state. C-channel data is transferred on the STBUS MSB first by the HPhone-II.
Ch2EN and Ch3EN - B1-Channel and B2-Channel
Channels 2 and 3 are the B1 and B2 channels,
respectively. These bits (Ch 2EN and Ch3EN)
are used to enable the PCM channels from/to
the HPhone-II as required.
Transmit PCM on DSTo
When high, PCM from the Filter/CODEC and DSP is
transmitted on DSTo in the selected ST-BUS
channel. When low, DSTo is forced to logic 0 for the
corresponding timeslot. If both Ch 2EN and Ch3EN
are enabled, default is to channel 2.
Receive PCM from DSTi
When high, PCM from DSTi is routed to the DSP and
Filter/CODEC in the associated channel. If both
Ch2EN and Ch 3EN are enabled the default is to
channel 2.
125 µs
F0i
DSTi,
DSTo
CHANNEL 0
D-channel
LSB first
for DChannel
CHANNEL 1
C-channel
CHANNEL 2
B1-channel
CHANNEL 3
B2-channel
CHANNELS 4 - 31
Not Used
MSB first for C, B1 - & B2Channels
Figure 7 - ST-BUS Channel Assignment
7-19
MT9092
New Call Tone
Watchdog
The New Call Tone Generator produces a frequency
shifted square-wave used to toggle the speaker
driver outputs. This is intended for use where a
ringing signal is required concurrently with an
already established voice conversation in the
handset.
To maintain program integrity an on-chip watchdog
timer is provided for connection to the
microcontroller reset pin. The watchdog output WD
(pin 17) goes high while the HPhone-II is held in
reset via the PWRST (pin 6). Release of PWRST will
cause WD to return low immediately and will also
start the watchdog timer. The watchdog timer is
clocked on the falling edge of F0i and requires only
this input, along with V DD, for operation.
Programming of the DSP for New Call generator is
exactly as is done for the tone ringer micro-program
except that the OPT bit (DSP Control Register,
address 1Eh) is set high. In this mode the DSP does
not produce a frequency shifted squarewave output
to the filter CODEC section. Instead the DSP uses
the contents of the tone coefficient registers, along
with the tone warble rate register, to produce a gated
squarewave control signal output which toggles
between the programmed frequencies. This control
signal is routed to the New Call Tone block when the
NCT EN control bit is set (General Control Register,
address 0Fh). NCT EN also enables a separate gain
control block, for controlling the loudness of the
generated ringing signal. With the gain control block
set to 0dB the output is at maximum or 6 volts p-p.
Attenuation of the applied signal, in three steps of 8
dB, provide the four settings for New Call tone (0, -8,
-16, -24 dB). The NCT gain bits (NCTG 0-NCTG1)
reside in the FCODEC Gain Control Register 2
(address 0Bh).
If the watchdog reset word is written to the watchdog
register (address 11h) after PWRST is released, but
before the timeout period (T=512mSec) expires, a
reset of the timer results and WD will remain low.
Thereafter, if the reset word is loaded correctly at
intervals less than 'T' then WD will continue low. The
first break from this routine, in which the watchdog
register is not written to within the correct interval or
it is written to with incorrect data, will result in a high
going WD output after the current interval 'T' expires.
WD will then toggle at this rate until the watchdog
register is again written to correctly.
5-BIT WATCHDOG RESET WORD
X
X
X
W4
W3
W2
W1
W0
0
1
0
1
0
x=don’t care
Test Loops
Detail LBio and LBoi Loopback Register (address
16h)
7-20
LBio
Setting this bit causes data on DSTi to be
looped back to DSTo directly at the pins. The
appropriate channel enables Ch 0EN -Ch3EN
must also be set.
LBoi
Setting this bit causes data on DSTo to be
looped back to DSTi directly at the pins.
MT9092
HPhone-II Register Map
Address
(Hex)
WRITE
READ
00
HDLC ADDRESS RECOGNITION REGISTER 1
VERIFY
01
HDLC ADDRESS RECOGNITION REGISTER 2
VERIFY
02
HDLC TRANSMIT FIFO
HDLC RECEIVE FIFO
03
HDLC CONTROL REGISTER 1
VERIFY
04
NOT USED
HDLC STATUS REGISTER
05
HDLC CONTROL REGISTER 2
VERIFY
06
HDLC INTERRUPT ENABLE REGISTER
VERIFY
07
NOT USED
HDLC INTERRUPT STATUS REGISTER
08
RESERVED
RESERVED
09
RESERVED
RESERVED
0A
FCODEC GAIN CONTROL REGISTER 1
VERIFY
0B
FCODEC GAIN CONTROL REGISTER 2
VERIFY
0C
RESERVED
RESERVED
0D
RESERVED
RESERVED
0E
TRANSDUCER CONTROL REGISTER
VERIFY
0F
GENERAL CONTROL REGISTER
VERIFY
10
RESERVED
RESERVED
11
WATCHDOG REGISTER
NOT USED
12
LCD SEGMENT ENABLE REGISTER 1
VERIFY
13
LCD SEGMENT ENABLE REGISTER 2
VERIFY
14
C-CHANNEL REGISTER (to DSTo)
C-CHANNEL REGISTER (from DSTi)
15
TIMING CONTROL REGISTER
VERIFY
16
LOOP-BACK REGISTER
VERIFY
17-1C
RESERVED
RESERVED
1D
RECEIVE GAIN CONTROL REGISTER
VERIFY
1E
DSP CONTROL REGISTER
VERIFY
1F
RESERVED
RESERVED
20
TRANSMIT AUDIO GAIN REGISTER
VERIFY
21
TRANSMIT DTMF GAIN REGISTER
VERIFY
22
RESERVED
RESERVED
23
TONE COEFFICIENT REGISTER 1
VERIFY
24
TONE COEFFICIENT REGISTER 2
VERIFY
25
RESERVED
RESERVED
26
TONE RINGER WARBLE RATE REGISTER
VERIFY
27-3F
RESERVED
RESERVED
7-21
MT9092
Register Summary
reference to review each of the control/status bit
definitions without the need to locate them in the text
of the functional block descriptions.
This section contains a complete listing of the
HPhone-II register addresses, the control/status bit
mapping associated with each register and a
definition of the function of each control/status bit.
The Register Summary may be used for future
HDLC Address Recognition Register 1
Adr16 Adr15 Adr14
7
6
5
ADDRESS = 00h WRITE/READ VERIFY
Adr13 Adr12 Adr11 Adr10
4
3
2
1
A1EN
Power Reset Value
0000 0000
0
Adr 16-11
A six bit mask used to interrogate the first byte of the received address. Adr16 is MSB. In the Q.921 specification these
bits are defined to be Sapi5-0.
Adr 10
This bit is used in address comparison if a seven bit address is being checked for (Control bit Seven of Control Register 2
is set). In the Q.921 specification this bit is defined to be C/R (Command/Response).
A1EN
When this bit is high, this six (or seven) bit mask is used in address comparison of the first address byte. If address
recognition is enabled, any packet failing the address comparison will not be stored in the RX FIFO. A1EN must be high
for All-call (1111111) address recognition for single byte address. When this bit is low, this bit mask is ignored in address
comparison.
HDLC Address Recognition Register 2
Adr26 Adr25 Adr24
7
6
5
ADDRESS = 01h WRITE/READ VERIFY
Adr23 Adr22 Adr21 Adr20
4
3
2
1
A2EN
Power Reset Value
0000 0000
0
Adr 26-20
A seven bit mask used to interrogate the second byte of the received address. Adr26 is MSB. This mask is ignored (as well
as first byte mask) if an All call address (1111111) is received. In the Q.921 specification these bits are defined to be
Tei6-0.
A2EN
When this bit is high this seven bit mask is used in address comparison of the second address byte. If address recognition
is enabled, any packet failing the address comparison will not be stored in the RX FIFO. A2EN must be high for All-call
address recognition. When this bit is low, this bit mask is ignored in address comparison.
HDLC Transmit/Receive FIFO Register
ADDRESS = 02h WRITE/READ
D7
D6
D5
D4
D3
D2
D1
D0
7
6
5
4
3
2
1
0
Power Reset Value
Not Applicable
The Transmitter FIFO is 19 words deep. Each word consists of 8 bits of data from the internal data bus and 2 status bits from CONTROL Register 1 (EOP and FA). If there is data in the Tx FIFO then the lowest data byte in it is loaded into an output shift register for
transmission, and the remaining data shifts down by one word position (Tx FIFO read). A write to a full Tx FIFO will update the top byte
only.
The receiver FIFO is 19 words deep. During a receiver write, the last 8 bits of a shift register buffer and two status bits are loaded into
7-22
MT9092
HDLC Control Register 1
ADDRESS = 03h WRITE/READ VERIFY
Adrec HRxEN HTxEN
7
Adrec
HRxEN
6
5
EOP
FA
Mark
Idle
Trans
-
4
3
2
1
0
Power Reset Value
0000 0000
When high this bit will enable address recognition. This forces the receiver to recognize only those packets having the
unique address as programmed in the Receive Address Recognition Registers or if the address is an All-Call address.
When low, all packets are recognized.
When low this bit will disable the HDLC receiver. The receiver will disable after the rest of the packet presently being
received is finished. When high the receiver will be immediately enabled (depending on the state of CHoEN) and will begin
searching for flags, Go-aheads etc.
HTxEN
When low this bit will disable the HDLC transmitter. The transmitter will disable after the completion of the packet presently
being transmitted. When high the transmitter will be immediately enabled (depending on the state of CHoEN) and will
begin transmitting data, if any, or go to a Mark idle or Interframe time fill state.
EOP
Forms a tag on the next byte written to the Tx FIFO and when set will indicate an EOP byte to the transmitter which will
transmit an FCS following this byte. This facilitates loading of multiple packets into Tx FIFO. This bit is reset automatically
after a write to the Tx FIFO occurs.
Forms a tag on the next byte written to Tx FIFO and when set will indicate to the transmitter that it should abort the packet
in which that byte is being transmitted. This bit is reset automatically after a write to the Tx FIFO.
When low, the transmitter will be in an idle state. When high it is in an Interframe time fill state. These two states will only
occur when the Tx FIFO is empty.
When high this bit will enable transparent mode. The HDLC will perform the serial-to-parallel and parallel-to-serial
conversion without inserting or deleting zeros. No CRC bytes are sent or monitored nor are flags, aborts or Go-aheads. No
address recognition is monitored. The receiver or transmitter must be enabled through Control Register 1 as well as
setting CH0EN.
FA
Mark Idle
Trans
HDLC Status Register
Idle
Intgen Chan
7
Intgen
Idle Chan
RxBS2,
RxBS1
Note
Txstat2,
Txstat1
Txstat Rxstat Rxstat
RxBS2 RxBS1 Txstat
2
1
2
1
6
5
4
3
2
1
Power Reset Value
00XX 1000
0
Is set to a 1 when an interrupt (in conjunction with the Interrupt Mask Register) has been generated by the HDLC. This is
an asynchronous event. It is reset when the Interrupt Register is read.
Is set to a 1 when an Idle Channel state (15 or more ones) has been detected by the receiver. This is an asynchronous
event. Status becomes valid after first 15 bits or the first zero bit received.
Indicates the status of the next byte to be read from the Rx FIFO.
RxBS2
RxBS1
Byte status
1
1
last byte (bad packet)
0
1
first byte
1
0
last byte (good packet)
0
0
packet byte
- If two consecutive first byte signals are received without an intervening last byte, then an overflow has occurred and the
first packet (or packets) are bad. A bad packet indicates that either a frame abort has occurred or the FCS did not match.
- On power-up these bits are in an indeterminate state until the first byte is written to Rx FIFO.
These two bits are encoded to indicate the present state of Tx FIFO. This is an asynchronous event.
Txstat1
Tx FIFO Status
Txstat2
0
0
TxFULL
0
1
5 OR MORE BYTES (15 if Fltx set)
1
1
4 OR LESS BYTES (14 if Fltx set)
1
Rxstat2,
Rxstat1
ADDRESS = 04h READ
0
TxEMPTY
These two bits are encoded to indicate the present state of Rx FIFO. This is an asynchronous event.
Rxstat1
Rx FIFO Status
Rxstat2
0
0
RxEMPTY
0
1
14 OR LESS BYTES (4 if Flrx set)
1
1
1
0
15 OR MORE BYTES (5 if Flrx set)
RxOVERFLOW EXISTS
Note: Bits marked "-" are reserved bits and should be written with logic "0".
7-23
MT9092
HDLC Control Register 2
Intsel
7
Intsel
Tcrci
Seven
Flrx
Fltx
Rxfrst
Txfrst
6
ADDRESS = 05h WRITE/READ VERIFY
Tcrci
Seven
Flrx
Fltx
Rxfrst
Txfrst
5
4
3
2
1
0
Power Reset Value
0000 0000
When high, this bit will cause bit 2 of the Interrupt Register to reflect a Transmit FIFO underrun (Txunder). When low, this
interrupt will reflect a frame abort (FA).
When high, this bit will inhibit transmission of the CRC. That is, the transmitter will not insert the computed CRC onto the bit
stream after seeing the EOP tag byte. The microprocessor then has the opportunity to insert the CRC as part of the data
field.
When high, this bit will enable seven bits of address recognition in the first address byte. The received address byte must
have bit 0 equal to 1 which indicates a single address byte is being received.
When high, this bit will change the Rx FIFO interrupt and status level from 15 to 5 bytes, thus allowing the microprocessor
more time to react to interrupt conditions.
When high, this bit will change the Tx FIFO interrupt and status level from 4 to14 bytes, thus allowing the microprocessor
more time to react to interrupt conditions.
When high, the Rx FIFO will be reset. This causes the receiver to be disabled until the next reception of a flag, an
occurrence which resets this bit. The Status Register will identify the FIFO as being empty. However, the actual bit values
of data in the Rx FIFO will not be reset.
When high, the Tx FIFO will be reset. The Status Register will identify the FIFO as being empty. This bit will be reset when
data is written to the Tx FIFO. The actual bit values of data in the Tx FIFO will not be reset..
HDLC Interrupt Enable Register
GA
7
ADDRESS = 06h WRITE/READ VERIFY
EOPD TEOP EOPR TxFL
6
5
4
3
FA/Tx
Under
RxFf
Rx
Ovfl
2
1
0
Power Reset Value
0000 0000
This register is used with the Interrupt Register to mask out the interrupts that are not required by the microprocessor. Interrupts that
are masked out will not produce an IRQ; however, they will set the appropriate bit in the Interrupt Register. An interrupt is disabled
when the microprocessor writes a 0 to a bit in this register. This register is cleared on power reset.
Note: Bits marked "-" are reserved bits and should be written with logic "0".
7-24
MT9092
HDLC Interrupt Status Register
GA
7
ADDRESS = 07h READ
EOPD TEOP EOPR
6
5
4
FA/Tx
TxFL Under
3
2
RxFf
Rx
Ovfl
1
0
Power Reset Value
0000 0000
This register indicates the source of an interrupt. It is used in conjunction with the Interrupt Enable Register to generate an interrupt. The
register is reset by the microprocessor read, which also resets the IRQ output. All interrupts are generated by a transition. That is, the
register informs the user that an interrupt did occur but may not presently be valid. To determine if the interrupt is presently valid the
Status Register should be polled. Due to the asynchronous nature of the interrupts, an interrupt occurring during a read of this register
will be saved until the read is over, unless it is an interrupt that has already been set.
GA
EOPD
Indicates a go-ahead pattern (011111110) was detected by the HDLC receiver.
This bit is set when an end of a packet (EOP) byte is written into the RX FIFO by the HDLC receiver. This can be in the
form of a flag, an abort sequence, or an invalid packet.
TEOP
This bit is set when the transmitter has finished sending the closing flag of a packet or after a packet has been aborted .
EOPR
This bit is set when the byte about to be read from the Rx FIFO is the last byte of the packet. It is also set if the Rx FIFO
is read and there is no data in it.
TxFL
Tx FIFO low indication. Indicates that a transition from 5 to 4 bytes in the Tx FIFO was detected. If Fltx is set then this will
be 15 to 14 bytes.
FA:TxUnder When Intsel bit of Control Register 2 is low this bit (FA) is set when a frame abort is received during packet reception. It
must be received after a minimum number of bits have been received (26) otherwise it is ignored (see HDLC FRAME
STRUCTURE). When Intsel is high this bit is set for a Tx FIFO underrun indication. Indicates that a read by the
transmitter was attempted on an empty Tx FIFO without an EOP or FA tagged byte.
RxFf
RxOvfl
Indicates that a transition from 14 to 15 bytes in the FIFO was detected. If Flrx is set then this will be 4 to 5 bytes.
Indicates that the Rx FIFO overflowed (i.e. an attempt to write to a full RX FIFO). The HDLC will always disable the
receiver once the receive overflow has been detected. The receiver will be re-enabled upon detection of the next flag, but
ADDRESS = 08h and 09h are RESERVED
FCODEC Gain Control Register 1
7
Receive Gain
Setting (dB)
ADDRESS = 0Ah WRITE/READ VERIFY
RxFG2 RxFG1 RxFG0
6
5
4
3
RxFG2
RxFG 1
RxFG0
Power Reset Value
X000 X000
TxFG2 TxFG1 TxFG0
2
1
0
Transmit Gain
Setting (dB)
TxFG 2
TxFG 1
TxFG 0
0
0
0
(default) 0
0
0
0
-1
0
0
1
1
0
0
1
-2
0
1
0
2
0
1
0
-3
0
1
1
3
0
1
1
-4
1
0
0
4
1
0
0
-5
1
0
1
5
1
0
1
-6
1
1
0
6
1
1
0
-7
1
1
1
7
1
1
1
(default)
0
RxFGn = Receive Filter Gain n
TxFGn = Transmit Filter Gain n
Note: Bits marked "-" are reserved bits and should be written with logic "0".
7-25
MT9092
FCODEC Gain Control Register 2
-
NCTG1 NCTG0
-
7
ADDRESS = 0Bh WRITE/READ VERIFY
6
5
4
-
STG2
3
2
Power Reset Value
0X00 X000
STG1 STG0
1
0
Side-tone Gain
STG 2
STG 1
STG 0
(default) OFF
0
0
0
-9.96
0
0
1
0
-6.64
0
1
0
1
-3.32
0
1
1
0
1
0
0
3.32
1
0
1
6.64
1
1
0
9.96
1
1
1
Gain (dB)
NCTG 1
NCTG0
0 (default)
0
0
-8
0
1
-16
1
-24
1
Setting (dB)
NCTGn = New Call Tone Gain n
STGn = Side-tone Gain n
ADDRESSES 0Ch and 0Dh are RESERVED
Transducer Control Register
PuFC
Tfhp
7
6
PuFC
DIAL
EN
5
ADDRESS = 0Eh WRITE/READ VERIFY
SIDE
EN
4
MIC
EN
3
MIC/
HNSTMIC
2
SPKR HSSPKR
EN
EN
1
0
Power Reset Value
0000 0000
SPKR EN
When high, the Filter/CODEC is powered up. When low, the Filter/CODEC is powered down. If PuFC, SPKR EN and
HSSPKR EN are all low then the VRef/VBias circuit is also powered down.
When high, an additional high pass function (passband beginning at 400Hz) is inserted into the transmit path. When
low, this highpass filter is disabled.
When high, a first order lowpass filter is inserted into the receive path (3dB = 1kHz). When low, this lowpass filter is
disabled.
When high, the sidetone path is enabled (assuming STG2-0 are not all low). When low, the sidetone path is disabled.
When high, the selected transmit microphone is enabled to the transmit filter section. When low, the microphone
path is muted.
When high, the handsfree microphone (pins MIC±) is muxed into the transmit path. When low, the handset
microphone (pins M±) is muxed into the transmit path. Both are contingent on 'MIC EN".
When high, the handsfree loudspeaker driver is powered up. When low, this driver is powered down.
HSSPKR EN
When high, the handset speaker driver is powered up. When low, this driver is powered down.
Tfhp
DIAL EN
SIDE EN
MIC EN
MIC/HNSTMIC
Note: Bits marked "-" are reserved bits and should be written with logic "0".
7-26
MT9092
General Control Register
RST
7
DATA
SEL
ADDRESS = 0Fh WRITE/READ VERIFY
A/µ
6
Sign-Mag/
CCITT
5
4
Rx
A/µ
MIC
A/µ
3
2
Side
A/µ
NCT
EN
1
0
Power Reset Value
0000 0000
RST
Active high reset. Performs the same function as PWRST but does not affect the microport or the watchdog circuits.
To remove this reset a PWRST must occur or this bit must be written low.
DATASEL
When high, the microport transmit and receive are performed on separate pins. DATA1 is receive while DATA2 is
transmit. When low, the microport conforms to Intel MCS-51 mode 0 specifications; DATA1 is a bi-directional
(transmit/receive) serial data pin while DATA2 is internally disconnected and tri-stated.
When high, A-Law (de)coding is selected. When low, µ-Law (de)coding is selected.
A/µ
Sign-mag/CCITT When high, sign-magnitude bit coding is selected, When low, true CCITT PCM coding is selected.
When high, the receiver driver nominal gain is set at -9.7 dB. When low this driver nominal gain is set at -12.3 dB.
RxA/µ
When high, the transmit amplifier nominal gain is set at 15.4 dB. When low this amplifier nominal gain is set at 6.1
MICA/µ
dB.
SIDEA/µ
When high, the side-tone nominal gain is set at -18.8 dB. When low this nominal gain is set at -11 dB.
NCT EN
When high, the new call tone generator output from the DSP is selected as the source for the loudspeaker path.
When low, the CODEC output is selected for the loudspeaker path. Note that SPKR EN must also be set high for
new call tone to function.
ADDRESS 10h is RESERVED
Watchdog Register
7
ADDRESS = 11h WRITE
-
-
6
5
W4
W3
W2
W1
W0
4
3
2
1
0
Power Reset Value
XXX0 1010
WATCHDOG RESET WORD - XXX01010
LCD Segment Enable Register 1
ADDRESS = 12h WRITE/READ VERIFY
SC8
SC7
SC6
SC5
SC4
SC3
SC 2
SC1
7
6
5
4
3
2
1
0
Power Reset Value
0000 0000
Twelve segment control bits used for the LCD outputs. When high the respective segment is on. When low the respective segment is
off.
LCD Segment Enable Register 2
ADDRESS = 13h WRITE/READ VERIFY
-
-
-
-
SC12
SC11
SC10
SC9
7
6
5
4
3
2
1
0
Power Reset Value
XXXX 0000
Twelve segment control bits used for the LCD outputs. When high the respective segment is on. When low the respective segment is
off.
Note: Bits marked "-" are reserved bits and should be written with logic "0".
7-27
MT9092
C-Channel Register
ADDRESS = 14h WRITE/READ
D7
D6
D5
D4
D3
D2
D1
D0
7
6
5
4
3
2
1
0
Power Reset Value
Write = 1111 1111
Read = Not Applicable
Micro-port access to the ST-BUS C-Channel information.
Timing Control Register
ADDRESS = 15h WRITE/READ VERIFY
-
-
-
-
7
6
5
4
CH3EN CH2EN CH1EN CH0EN
3
2
1
Power Reset Value
XX0X 0000
0
All bits active high:
Ch2EN and Ch3EN
Channels 2 and 3 are the B1 and B2 channels, respectively. PCM associated with the DSP, Filter/CODEC and transducer audio paths is conveyed in one of these channels as selected in the timing control register.
Transmit B1 and B2 data on DSTo
When high PCM from the Filter/CODEC and DSP is transmitted on DSTo in the associated channel. When low
DSTo is forced to logic 0 for the corresponding timeslot. If both Ch2EN and Ch3EN are enabled, data defaults to
channel 2.
Receive B1 and B2 data on DSTi
When enabled PCM from DSTi is routed to the DSP and Filter/CODEC in the associated channel. If both Ch2EN
and Ch3EN are enabled, data input defaults to channel 2.
Ch1EN
Channel 1 conveys the control/status information for the layer 1 transceiver. The full 64kb/s bandwidth is available and
is assigned according to which transceiver is being used. Consult the data sheets for the transceiver selected. When
high register data is transmitted on DSTo. When low this timeslot is tri-stated on DSTo. Receive C-Channel data (DSTi)
is always routed to the register regardless of this control bit's logic state.
Ch0EN
Channel 0 conveys the D-Channel HDLC information. Since this function is dedicated to 16kb/s operation, only the first
Loop-back Register
7
ADDRESS = 16h WRITE/READ VERIFY
LBio
LBoi
-
-
-
-
-
6
5
4
3
2
1
0
Power Reset Value
X00X XXXX
LBio
Active high enables data from the ST-BUS input to be looped back to the ST-BUS output directly at the pins. The DSTo tri-
LBoi
Active high enables data from ST-BUS output to be looped back to the ST-BUS input directly at the pins.
state driver must also be enabled using one of the channel enable signals.
ADDRESS 17h-1Ch are RESERVED
Note: Bits marked "-" are reserved bits and should be written with logic "0".
7-28
MT9092
Receive Gain Control Register
ADDRESS = 1Dh WRITE/READ VERIFY
-
AUTO
B5
B4
B3
B2
B1
B0
7
6
5
4
3
2
1
0
Power Reset Value
0000 0000
AUTO
When high autonulling of the transmit PCM is enabled. When low, autonulling is disabled. This bit is used in conjunction with
B5-B0
These 6 bits (indicated below in hexadecimal) are decoded to control Rx pcm gain:
the PS2 - PS0 bits of the DSP Control Register at address 1Eh.
B5-B0
Gain Setting (dB)
B5-B0
Gain Setting (dB)
3F
3E
3D
3C
3B
3A
39
38
37
36
35
34
33
32
31
30
2F
2E
2D
2C
2B
2A
29
28
27
26
25
24
23
22
21
20
+22.5
+21.0
+19.5
+18.0
+16.5
+15.0
+13.5
+12.0
+10.5
+9.0
+7.5
+6.0
+4.5
+3.0
+1.5
+0.0
-1.5
-3.0
-4.5
-6.0
-7.5
-9.0
-10.5
-12.0
-13.5
-15.0
-16.5
-18.0
-19.5
-21.0
-22.5
-24.0
1F
1E
1D
1C
1B
1A
19
18
17
16
15
14
13
12
11
10
0F
0E
0D
0C
0B
0A
09
08
07
06
05
04
03
02
01
00
-25.5
-27.0
-28.5
-30.0
-31.5
-33.0
-34.5
-36.0
-37.5
-39.0
-40.5
-42.0
-43.5
-45.0
-46.5
-48.0
-49.5
-51.0
-52.5
-54.0
-55.5
-57.0
-58.5
-60.0
-61.5
-63.0
-64.5
-66.0
-67.5
-69.0
-70.5
-72.0
Note: B0-B5 of addresses 20h and 21h are encoded in the same manner
Note: Bits marked "-" are reserved bits and should be written with logic "0".
7-29
MT9092
DSP Control Register
ADDRESS = 1Eh WRITE/READ VERIFY
PS2
PS1
7
6
OPT:
RxMUTE:
TxMUTE:
DRESET:
PS0
5
OPT
RxMUTE
TxMUTE
-
DRESET
4
3
2
1
0
Power Reset Value
0000 0000
When high, the tone ringer is in New Call tone mode. When low the normal tone ringer program is executed.
This bit when high turns off the receive PCM channel, substituting quiet code.
This bit when high turns off the transmit PCM channel, substituting quiet code.
This bit (when high) enables the DSP. If low, no programs are executed, the master clock is disabled and the
program counter is reset to zero.
These bits are program select bits for the DSP Rom programs.
PS2-PS0:
PS2
PS1
PS0
0
0
0
Power up reset program
0
0
1
Gain control program
0
1
0
DTMF & Gain control program
0
1
1
Tone Ringer & Gain control program
1
0
0
Handsfree program
1
0
1
Reserved
1
1
0
Reserved
1
1
1
Reserved
MICRO-PROGRAM
Transmit Audio Gain Register
-
7
6
ADDRESS = 20h WRITE/READ VERIFY
B5
B4
B3
B2
B1
B0
5
4
3
2
1
0
Power Reset Value
XX11 0000
This register controls the transmit speech path gain in 1.5dB steps as in Receive Gain Register (address 1Dh).
ADDRESS = 21h WRITE/READ VERIFY
Transmit DTMF Gain Register
-
7
6
B5
B4
B3
B2
B1
B0
5
4
3
2
1
0
Power Reset Value
XX10 1110
This register controls the transmit DTMF level in 1.5dB steps as in Receive Gain Register (address 1Dh).
ADDRESS 22h is RESERVED
Note: Bits marked "-" are reserved bits and should be written with logic "0".
7-30
MT9092
Tone Coeff Register 1-DTMF or Tone Ringer
ADDRESS = 23h WRITE/READ VERIFY
B7
B6
B5
B4
B3
B2
B1
B0
7
6
5
4
3
2
1
0
Power Reset Value
0000 0000
This register is used to program the low-group frequency of the DTMF program. The tone coefficient is calculated as follows:
COEF = 0.128 x Frequency
where: Frequency is in Hz (note: COEF must be converted to an 8 bit binary integer)
Highest frequency possible:
1992.2 Hz
Lowest frequency possible:
7.8 Hz
Frequency resolution:
7.8 Hz
Pre-twist:
-2.1dB ± 0.2dB
This register is used to program the first frequency of the squarewave ringer program. The tone coefficient is calculated as follows:
COEF = 8000 / Frequency
where: Frequency is in Hz (note: COEF must be rounded off and converted to an 8 bit binary integer)
Highest frequency possible:
4000 Hz
Lowest frequency possible:
31.4 Hz
Frequency resolution:
non-linear
Tone Coeff Register 2-DTMF or Tone Ringer
ADDRESS = 24h WRITE/READ VERIFY
B7
B6
B5
B4
B3
B2
B1
B0
7
6
5
4
3
2
1
0
Power Reset Value
0000 0000
This register is used to program the high-group frequency of the DTMF program. The tone coefficient is calculated as follows:
COEF = 0.128 x Frequency
where: Frequency is in Hz (note: COEF must be converted to an 8 bit binary integer)
Highest frequency possible:
1992.2 Hz
Lowest frequency possible:
7.8 Hz
Frequency resolution:
7.8 Hz
Pre-twist:
0dB
This register is used to program the second frequency of the squarewave program. The tone coefficient is calculated similarly to tone
ADDRESS 25h is RESERVED
Tone Ringer Warble Rate-Tone Ringer
ADDRESS = 26h WRITE/READ VERIFY
B7
B6
B5
B4
B3
B2
B1
B0
7
6
5
4
3
2
1
0
Power Reset Value
0000 0000
The tone ringer will switch between squarewave frequencies at a warble frequency defined by this register. The relationship between
the duration period of each tone and the 8 bit warble coefficient is as follows:
Tone duration (warble frequency) = 500 / COEF
where: Frequency is in Hz, and 0≤COEF <256
Highest frequency possible:
500 Hz
Lowest frequency possible:
2.0 Hz
Addresses: 27h to 2Dh are transmit and receive gains and coefficients used by the filters in the handsfree
decision circuit.
2Eh to 3Fh are scratch-pad ram locations used by the DSP algorithms as temporary storage during calculations.
7-31
MT9092
Applications
To maintain a fully differential topology in the
transmit path the suggested connection scheme for
the transmit microphones is shown in Figure 8.
However, it is possible to use a single-ended
arrangement as shown in Figure 9 for the transmit
interface. In this case the dynamic range of the
MT9092 is reduced by half. In both figures the output
drivers are connected in a fully differential manner.
transmisssion devices which connect directly with
the MT9092 to complete an application; the MT8930
(SNIC) and the MT8971/72 (DSIC/DNIC). An ISDN
4-wire "TE" function is implemented with the
MT8930/MT9092 combination. A 2-wire digital phone
for PABX, key-systems and other proprietary
applications is implemented with the MT8971/72/
MT9092 combination.
Figures 10 and 11 show the 4-wire and 2-wire
applications, respectively.
The MT9092 is a member of the Mitel family of digital
terminal equipment components. There are two
330Ω
+5V
+
+
-
Av = 1+
0.1µF
100K
R
2R
T
+
VBias
T
R
100K
10µF
511Ω
0.1µF
-
Electret
Microphone
330Ω
511Ω
+5V
+
+
100K
R
2R
Av = 1+
T
0.1µF
T
R
0.1µF
100K
6
DSTi
DSTo
5
4
3
2
1
44
+
Electret
Microphone
0.1µF
511Ω
43 42 41 40
7
39
8
38
9
37
10
36
11
35
IRQ
SCLK
DATA2
DATA1
CS
WD
+
40Ω nom.
32Ω min.
C4i
F0i
12
75Ω
150Ω
MT9092
+5V
75Ω
34
13
33
14
32
15
31
16
30
17
29
18 19 20 21 22 23 24 25 26 27 28
.1µF 1000pF
1000pF
LCD
1000pF caps
are optional
Note: Single-ended configurations reduce
dynamic range by a factor of two.
LCD
Figure 8 - Application Circuit - fully differential audio input
7-32
10µF
511Ω
-
+5V
Serial
Microport
INTEL
MCS-51
0.1µF
VBias
+
VBias
ST-BUS
Port
to
Transmission
Device
+
-
MT9092
+
+5V
VBias
–
330Ω
+
T
1µF
R
10µF
1K
+
Electret
Microphone
330Ω
VBias
+
–
+5V
+
T
10µF
1K
1µF
R
+
Electret
Microphone
0.1µF
0.1µF
VBias
+5V
6
ST-BUS
Port
to
Transmission
Device
4
3
2
1
44 43 42 41 40
DSTi
7
39
DSTo
8
38
9
37
10
36
11
35
C4i
F0i
MT9092
40Ω nom.
32Ω min.
75Ω
+5V
75Ω
34
SCLK 13
33
14
32
DATA2
+
150Ω
IRQ 12
Serial
Microport
INTEL
MCS-51
5
DATA1 15
31
CS 16
30
WD 17
29
.1µF 1000pF
1000pF
1000pF caps
are optional
LCD
Note: Single-ended configurations reduce
dynamic range by a factor of two.
18 19 20 21 22 23 24 25 26 27 28
LCD
Figure 9 - Application Circuit - single-ended audio input
7-33
MT9092
LTx
HSPKR+
C4b
C4i
F0b
F0i
HSPKR-
CCITT ISDN
Reference
Point S
Interface
5 Volts
VBias
DC to DC
Converter
MT8930
SNIC
with
HDLC
Controller
DSTo
DSTi
DSTi
DSTo
AD0-7
MT9092
HPhone-∏
M+
Digital
Telephone
with
HDLC
Controller
M-
Handset
MIC+AAAAA
AAAAA
MIC- AAAA
AAAAAA Microphone
AAAAA
SPKR+
LRx
IRQ
(ALE)
(RD)
SPKR-
IRQ
CS
(WR)
SCLK
AS
(ALE)
Speaker
DATA1
E
(RD)
R/W
(WR)
AD0-7
8051
INTEL
IRQ
MCS51
Figure 10 - CCITT ISDN Voice/Data Terminal Equipment - TE1
5 volts
DC to DC
CONVERTER
C4i
F0
F0i
HSPKR+
HSPKR-
MT8972
Lin
DNIC
ZT
Twisted Pair
to Central
PBX
C4
Lout
DSTo
DSTi
DSTi
DSTo
MT9092
HPhone-∏
Digital
Telephone
with
HDLC
Controller
M+
Handset
MMIC+ AAAAA
AAAA
AAAAAAA Microphone
MIC- AAAA
AAAAA
SPKR+
SPKR10.24 MHz
IRQ SCLK CS
DATA1
INTEL
MCS-51
Figure 11 - Voice/Data Digital Telephone Set Circuit
7-34
Speaker
MT9092
Programming Examples
that these steps are from the power-up reset default
definition. If some other state is currently true then
some programming steps may be omitted while new
ones may be required.
Some examples of the programming steps required
to set-up various telephony functions are given. Note
Standard Full-duplex handset call
Description
select B-Channel of operation
Address
15h
DATA
bits 2 or 3 (as required)
reset DSP
set Rx gain (ie 0dB with Tx
set Tx gain (ie 0dB)
start Rx gain program
1Eh
1Dh
20h
1Eh
00h
70h (or as required)
30h (or as required)
21h
select transducers and turn on
sidetone and filter/CODEC
0Eh
99h
set sidetone gain
0Bh
04h (for 0dB or as required)
optional:
set CODEC Rx and Tx gain
select A-Law versus µ-Law
0Ah
0Fh
as required (0dB default)
bits 1-5 (as required)
Description
select B-Channel of operation
Address
15h
DATA
bits 2 or 3 (as required)
reset DSP
set Rx gain (ie 12 dB)
set Tx gain (ie 0dB)
start handsfree program
1Eh
1Dh
20h
1Eh
00h
38h (or as required)
30 h (or as required)
81h
select transducers and filter/CODEC
and turn off sidetone
0Eh
1Eh
0Ah
0Fh
as required (0dB default)
bits 1-5 (as required)
Description
select B-Channel of operation
Address
15h
DATA
bits 2 or 3 (as required)
reset DSP
set Rx gain (ie 0 dB with Tx
autonull)
set Tx gain (ie 0dB)
write tone coefficient 1
write tone coefficient 2
write warble tone rate coefficient
start tone ringer program
1Eh
1Dh
00h
70h (or as required)
20h
23h
24h
26h
1Eh
30h (or as required)
as required
as required
as required
61h
select speaker and filter/CODEC
and turn off sidetone
0Eh
82h
control ringer cadence by toggling
RxMUTE
1Eh
61
69
61
69
autonull)
Half-Duplex handsfree operation
optional:
set CODEC Rx and Tx gain
select A-Law versus µ-Law
Generate tone ringer
(on)
(off)
(on)
(off) etc...
7-35
MT9092
Generate DTMF tones
Description
select B-Channel of operation
Address
15h
DATA
bits 2 or 3 (as required)
reset DSP
set Rx DTMF gain (ie -20 dBm0)
set Tx audio gain (ie 0dB)
set Tx DTMF gain (ie -4dBm0)
write tone coefficient 1
write tone coefficient 2
start DTMF program
1Eh
1Dh
20h
21h
23h
24h
1Eh
00h
22h (or as required)
30h (or as required)
2Eh (or as required)
as required
as required
41h
select transducers and filter/CODEC
(PuFC)
and turn off sidetone
0Eh
as required
0Ah
as required (0dB default)
1Eh
as required
optional:
set CODEC Rx gain
send tones in only Rx or Tx by
disabling
RxMUTE or TxMUTE appropriately
New Call Tone
Description
Address
DATA
Assume that a B-Channel of operation has already been selected for the concurrent handset
conversation.
If this is not true select one.
select B-Channel of operation
15h
bits 2 or 3 (as required)
reset DSP
1Eh
00h
**********************************************************************************
set Rx gain (ie 0 dB with Tx autonull)
set Tx gain (ie 0dB)
1Dh
20h
70h (or as required)
30h (or as required)
Note: these two steps a required for the concurrent conversation only and do not affect new
call tone generation. See Standard Full-duplex handset call for required programming.
**********************************************************************************
write
write
write
start
23h
24h
26h
1Eh
as required
as required
as required
71h
set new call tone gain
0Bh
NCTG2-1 (as required)
select speaker
0Eh
enable new call tone
0Fh
02h
9Bh (assuming a concurrent handset
call)
01h (assuming all other bits are µ-Law
control ringer cadence by toggling
between gain control and tone ringer
with gain control programs
1Eh
7-36
tone coefficient 1
tone coefficient 2
warble rate coefficient
new call tone ringer program
71h (on)
31h (off)
71h (on) etc...
MT9092
Absolute Maximum Ratings
Parameter
Symbol
Min
Max
Units
VDD-VSS
-0.3
7
V
VI/VO
VSS-0.3
VDD+0.3
V
±20
mA
+150
°C
PD
750
mW
±2.0
KV
1
Supply Voltage
2
Voltage on any I/O pin
3
Current on any I/O pin (transducers excluded)
II/IO
4
Storage Temperature
TS
5
Power Dissipation (package)
6
Static Discharge
ESD
7
Latch-up Current
ILU
Plastic
-65
±100
mA
Recommended Operating Conditions - Voltages are with respect to VSS unless otherwise stated.
Characteristics
Sym
Min
Typ
Max
Units
5
5.25
V
Test Conditions
1
Supply Voltage
VDD
4.75
2
Input Voltage (high) *
VIH
2.4
VDD
V
Noise margin = 400mV
3
Input Voltage (low) *
VIL
VSS
0.4
V
Noise margin = 400mV
4
Operating Temperature
TA
-40
+85
°C
5
Clock Frequenecy (C4i)
fCLK
4092
4100
kHz
4096
* Excluding PWRST which is a Schmitt Trigger Input.
Power Characteristics
Characteristics
1
Supply Current (clock enabled, all
functions off
2
Supply Current by function
Filter/Codec
HDLC
DSP
Handset Driver (bias only, no signal)
Speaker Driver (bias only, no signal)
Timing Control, C-Channel, ST-BUS,
etc.
Total all functions enabled
Sym
Min
Typ
IDDC1
IDDF1
IDDF2
IDDF3
IDDF4
IDDF5
IDDF6
1.5
1.0
1.5
1.5
1.5
1.0
IDDFT
8.0
Max
Units
6
mA
mA
mA
mA
mA
mA
mA
14
mA
Test Conditions
See Note 1.
See Note 1.
See Note 2.
Note 1: Power delivered to the load is in addition to the bias current requirements.
Note 2: I DDFT is not additive to IDDC1 .
7-37
MT9092
DC Electrical Characteristics† (except LCD Drive Pins) - Voltages are with respect to ground (VSS) unless
otherwise stated.
Characteristics
Sym
Min
1
Input HIGH Voltage TTL inputs
VIN
2.0
2
Input LOW Voltage TTL inputs
VIL
3
VBias Voltage Output
4
Input Leakage Current 1
5
Positive Going Threshold
Voltage (PWRST only)
Negative Going Threshold
Voltage (PWRST only)
VT+
6
Output HIGH Current TTL O/P
IOH
-10
7
Output LOW Current TTL O/P
IOL
5
8
Output Voltage
9
Typ‡
Max
Units
Test Conditions
V
0.8
VBias
VDD/2
IIZ
0.1
V
V
Max. Load = 10kΩ
µA
VIN = VDD to VSS
-16
mA
VOH = 2.4V DSTo, WD,
DATA1,
DATA2, IRQ
10
mA
VOL = 0.4V DSTo, WD,
DATA1,
DATA2, IRQ
VRef
(VDD /2)
-1.5
V
Output Leakage Current 1
IOZ
0.01
10
Output Capacitance
Co
15
pF
11
Input Capacitance
Ci
10
pF
3.3
10
1.5
VT-
10
µA
No load
VOUT = VDD and VSS
† DC Electrical Characteristics are over recommended temperature and range & recommended power supply voltages.
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
1 TTL compatible pins only.
DC Electrical Characteristics† - LCD Drive Pins - Voltages are with respect to ground (VSS) unless otherwise
stated.
Characteristics
Sym
Min
Typ
Max
Units
Test Conditions
1
Output High Voltage Both
Segment and Backplane
VOH
4.8
---
---
Volts
Io = 1mA, VDD = 5V
2
Output Low Voltage Both
Segment and Backplane
VOL
---
---
0.2
Volts
Io = 1mA, VDD = 5V
3
Segment Output Load
---
---
1200
pF
4
Backplane Output Load
---
---
7200
pF
5
Frequency
62
62.5
63
Hz
7-38
MT9092
AC Characteristics† for A/D (Transmit) Path - 0dBm0 = 1.421Vrms for µ-Law and 1.477Vrms for A-Law, at the
CODEC. (VRef = 0.5 volts and VBias = 2.5 volts). All parameters pertain exclusively to the Filter/CODEC except absolute half-channel gain
and transmit idle channel noise.
Characteristics
Sym
Min
Typ‡
Max
5.79
6.0
1
Analog input equivalent to
overload decision
ALi3.17
ALi3.14
2
Absolute half-channel gain.
Transmit filter gain = 0dB setting
GAX1
GAX2
5.4
14.7
All other transmit filter settings
(1 to 7dB) are in addition to 0dB
setting
GAX1
GAX2
3
Gain tracking vs. input level
CCITT G.714 Method 2
4
6.1
15.4
Units
Vp-p
Vp-p
Test Conditions
µ-Law
A-Law
Both at CODEC
6.8
16.1
dB
dB
MICA/u=0*
MICA/u=1*
MIC± or M± to PCM
1020Hz
-0.15
-0.15
+0.15
+0.15
dB
dB
MICA/u=0*
MICA/u=1*
from nominal
MIC± or M± to PCM
1020Hz
GTX
-0.3
-0.6
-1.6
0.3
0.6
1.6
dB
dB
dB
3 to -40 dBm0
-40 to -50 dBm0
-50 to -55 dBm0
Signal to total Distortion vs.
input level.
CCITT G.714 Method 2
DQX
35
29
24
dB
dB
dB
0 to -30dBm0
-40 dBm0
-45 dBm0
5
Transmit Idle Channel Noise
NCX
NPX
6
Gain relative to gain at 1020Hz
<50 Hz
60 Hz
200 Hz
300-3000 Hz
3000-3400 Hz
4000 Hz
>4600 Hz
GRX
7
Absolute Delay
DAX
360
µs
at frequency of minimum
delay
8
Group Delay relative to D AX
DDX
750
380
130
750
µs
µs
µs
µs
500-600 Hz
600-1000 Hz
1000-2600 Hz
2600 - 2800 Hz
9
Power Supply Rejection
f=1020 Hz
f=0.3 to 3 kHz
f=3 to 4 kHz
f=4 to 50 kHz
15
-72
-0.25
-0.9
PSSR
PSSR1
PSSR2
PSSR3
37
40
35
40
17.5
-66
dBrnC0
dBrn0p
-25
-30
0.0
0.25
0.25
-12.5
-25
dB
dB
dB
dB
dB
dB
dB
dB
dB
dB
dB
µ-Law
A-Law
±1000mVrms peak signal
µ-Law
PSSR1-3 not production
tested
† AC Electrical Characteristics are over recommended temperature range & recommended power supply voltages.
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
* Note: MICA/u, refer to General Control Register, address 0Fh.
7-39
MT9092
AC Characteristics† for D/A (Receive) Path - 0dBm0 = 1.421Vrms for µ-Law and 1.477Vrms for A-Law, at the
CODEC. (VRef = 0.5volts and VBias = 2.5 volts). All parameters pertain exclusively to the Filter/CODEC except absolute gain and receive
idle channel noise.
Characteristics
Sym
Min
1 Analog output at the CODEC full
scale
ALo3.17
ALo3.14
2 Absolute half-channel gain.
Receive filter gain = 0dB setting
GAR1
GAR2
GAR3
-0.6
-12.9
-10.3
All other receive filter settings
(-1 to -7dB) are in addition to
0dB setting
GAR1
GAR2
GAR3
3 Gain tracking vs. input level
CCITT G.714 Method 2
Typ‡
Max
5.704
5.906
Test Conditions
µ-Law
A-Law
Vp-p
Vp-p
0.95
-11.8
-9.1
dB
dB
dB
PCM to SPKR±
PCM to HSPKR±, RxA/u=0*
PCM to HSPKR±, RxA/u=1*
1020Hz
-0.15
-0.15
-0.15
+0.15
+0.15
+0.15
dB
dB
dB
PCM to SPKR±
PCM to HSPKR±, RxA/u=0*
PCM to HSPKR±, RxA/u=1*
from nominal
1020Hz
GTR
-0.3
-0.6
-1.6
0.3
0.6
1.6
dB
dB
dB
3 to -40 dBm0
-40 to -50 dBm0
-50 to -55 dBm0
4 Signal to total distortion vs. input
level.
CCITT G.714 Method 2
GQR
35
29
24
dB
dB
dB
0 to -30dBm0
-40 dBm0
-45 dBm0
5 Receive Idle Channel Noise
NCR
NPR
6 Gain relative to gain at 1020Hz
200 Hz
300-3000 Hz
3000-3400 Hz
4000 Hz
>4600 Hz
GRR
7 Absolute Delay
DAR
240
µs
at frequency of min. delay
8 Group Delay relative to DAR
DDR
750
380
130
750
µs
µs
µs
µs
500-600 Hz
600-1000 Hz
1000-2600 Hz
2600 - 2800 Hz
9 Crosstalk
CTRT
CTTR
dB
dB
G.714.16
D/A to A/D
A/D to D/A
0.2
-12.3
-9.7
Units
-0.25
-0.90
15.5
-75
dBrnC0
dBrn0p
0.25
0.25
0.25
-12.5
-25
dB
dB
dB
dB
dB
-74
-80
µ-Law
A-Law
† AC Electrical Characteristics are over recommended temperature range & recommended power supply voltages.
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
* Note: RxA/u, refer to General Control Register, address 0Fh.
AC Electrical Characteristics† for Side-tone Path
Sym
Min
Typ‡
Max
Units
Test Conditions
Absolute path gain
Gain adjust = 0dB
GAS1
GAS2
-17.2
-13.1
-16.7
-12.6
-16.2
-12.1
dB
dB
SIDEA/u, MICA/u, RxA/u all 0
SIDEA/u, MICA/u, RxA/u all 1
M± inputs to HSPKR± outputs
1000Hz
All other settings
(-9.96 to +9.96dB)
GAS
GAS
-0.3
-0.3
+0.3
+0.3
dB
dB
SIDEA/u=0
SIDEA/u=1
from nominal
relative measurements w.r.t.
GAS1 & GAS2
Characteristics
1
† AC Electrical Characteristics are over recommended temperature range & recommended power supply voltages.
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
7-40
MT9092
AC Electrical Characteristics† for New Call Tone
Characteristics
1
New Call Tone Output voltage
(SPKR+ to SPKR-)
Sym
Typ‡
Units
Test Conditions
VNCT1
VNCT2
VNCT3
VNCT4
6.0
2.390
0.950
0.380
Vp-p
Vp-p
Vp-p
Vp-p
NCTG0=0, NCTG1=0
NCTG0=1, NCTG1=0
NCTG0=0, NCTG1=1
NCTG0=1, NCTG1=1
load > 34 ohms across SPKR±
† AC Electrical Characteristics are over recommended temperature range & recommended power supply voltages.
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
Electrical Characteristics† for Analog Outputs
Characteristics
Sym
Min
Typ‡
260
300
ohms
300
pF
each pin:
%
300 ohms load across
HSPKR± (tol-15%),
Vo≤6.2Vp-p,RxA/u=1,
Rx gain=0dB
1
Earpiece load impedance
EZL
2
Allowable Earpiece capacitive
load
ECL
3
Earpiece harmonic distortion
ED
4
Speaker load impedance
SZL
5
Allowable Speaker capacitive
load
SCL
6
Speaker harmonic distortion
SD
Max
0.5
34
Units
Test Conditions
across HSPKR±
HSPKR+
HSPKR-
40
ohms
300
pF
each pin
%
40 ohms load across SPKR±
(tol-15%),
VO≤6.2Vp-p, Rx gain=0dB
0.5
across SPKR±
SPKR+
SPKR-
† Electrical Characteristics are over recommended temperature range & recommended power supply voltages.
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
Electrical Characteristics† for Analog Inputs
Characteristics
Sym
1
Differential input voltage without
overloading CODEC
VID
2
Input impedance
ZI
Min
50
Typ‡
Max
Units
Test Conditions
2.87
1.02
Vp-p
Vp-p
MICA/u=0, A/u=0
MICA/u=0, A/u=1
across MIC± or M± inputs,
Tx filter gain = 0dB setting
kΩ
MIC+, MIC-, M+ or Mto VSS.
† Electrical Characteristics are over recommended temperature range & recommended power supply voltages.
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
7-41
MT9092
AC Electrical Characteristics† - ST-BUS Timing (See Figure 12)
Characteristics
Sym
Min
Typ‡
Max
Units
1
C4i Clock Period
tC4P
243
244
245
ns
2
C4i Clock High Period
tC4H
121
122
123
ns
3
C4i Clock Low Period
tC4L
121
122
123
ns
4
C4i Clock Transition Time
20
50
ns
5
F0i Frame Pulse Setup Time
tF0iS
50
ns
6
F0i Frame Pulse Hold Time
tF0iH
50
ns
7
F0i Frame Pulse Width Low
tF0iW
150
ns
8
DSTo Delay
tDSToD
9
DSTi Setup Time
tDSTiS
30
ns
10
DSTi Hold Time
tDSTiH
50
ns
tT
100
125
ns
Test Conditions
CL=50 pF
† Timing is over recommended temperature range & recommended power supply voltages.
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
tT
tC4H
tC4P
C4i
tT
1 bit cell
2.4V
0.4V
tDSToD
DSTo
2.4V
0.4V
tDSTiS
DSTi
tDSTiH
2.4V
0.4V
tT
F0i
2.4V
0.4V
tF0iH
tF0iS
tT
tF0iW
Figure 12 -ST-BUS Timing Diagram
7-42
tC4L
MT9092
AC Electrical Characteristics† - Microport Timing (see Figure 13)
Characteristics
Sym
Min
Typ‡
Max
Units
Test Conditions
1
Receive data setup
A
10
ns
2
Receive data hold
B
10
ns
3
Transmit data delay from clock
falling edge
C
80
ns
50 pF
4
High Z to valid data from SCLK
falling edge
D
80
ns
50 pF
5
Valid data to high Z from CS rising
edge
E
80
ns
50 pF
6
Current transmit data hold
from clock falling edge
F
0
ns
7
Chip Select to SCLK setup and
hold times
G
0
ns
8
SCLK clock period (3 MHz)
H
333
ns
† Timing is over recommended temperature range & recommended power supply voltages.
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
DATA 1
RECEIVE
0
1
2
7
B
A
H
SCLK
G
G
CS
D
E
F
C
DATA 1 or DATA 2
TRANSMIT
0
1
2
6
7
Figure 13 - Serial Microport Timing Diagram
7-43
MT9092
NOTES:
7-44