Introduction
This document describes how to calculate DSP resource consumption for newly updated hardware that began shipping from Sonus Networks as of November 2016. For DSP consumption associated with older versions of hardware, please refer to the appropriate release documentation on the Sonus Documentation Portal.
Purpose
This guide is intended to help partners and customers regarding the capacity and use of DSP resources in the newly updated hardware that began shipping as of November 2016, with the expectation that partners and customers select the appropriate instance of
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to satisfy call deployment requirements.
How to Use This Guide
This guide is intended to be used by Sonus customers to help select a
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configuration instance that includes an appropriate quantity of DSP resources to support a given density of call sessions subject to DSP-related media intervention. The available
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configurations, along with a description of embedded features and options (including DSP resources and supported I/O), is
available behind the partner portal.
What You Need to Know
Default transcoding scenario: The most common IP ↔ IP transcoding scenario for SBC 1000 is from G.711 (RTP) to G.711 (SRTP). This is considered as the default transcoding scenario for SBC 1000 when calculating DSP resource requirements.
DSP resource: A DSP resource is a unit of DSP processing required to transcode from one codec to another. For SBC 1000, 1 DSP resource is equal to the processing associated with 1 (one) transcoding session for the default transcoding scenario (described above).
DSP resource requirement number: The number of DSP resources required to support a specific number of IP ↔ IP sessions. All calculations mentioned in this document build upon the default transcoding scenario mentioned above. For example, DSP resource requirement number for 100 IP ↔ IP sessions for a default transcoding scenario is 100.
Special case for multiple low-bit rate codecs: If two or more low-bit rate codecs (G.729ab, G.723.1, G.726, or T.38) are used (IP ↔ IP and/or TDM/IP), a 20% uplift is applied to the DSP resource requirement number.
Example: Two or more low-bit-rate codecs are used.
DSP Resource Requirement | 100 |
Plus 20% Uplift | 20 |
True DSP Resource Requirements | 120 |
Notes:
This uplift requirement only applies for multiple low-bit-rate codecs (G.729ab, G.723.1, G.726, or T.38).
The combination of a single low-bit rate codec with G.711 does not require an uplift.
It is also important to design for the most DSP-intensive usage. If multiple codecs are used and the split among these codecs varies, be sure to calculate using the codec that is most DSP-intensive and then apply the 20% uplift.
Multiplication Factor: Value derived from Table 1. The multiplication factor, when multiplied by the number of sessions required for your deployment, gives you the total number of DSP resources required for those sessions and selected codecs.
DSP Mode: Implies a session that is to be acted upon by the DSPs; i.e., a session requiring media services.
RTP Proxy Mode: A session that is not subject to DSP services but does flow through the
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for non-media intervention purposes (e.g., IP headers being modified for security purposes, etc.) is considered a session running in RTP Proxy mode. For clarity, sessions running in RTP Proxy mode do not use any DSP resources.
Direct Media Mode: A session that is not subject, and does not flow through, the
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is considered a session running in Direct Media mode. For clarity, sessions running in Direct Media mode do not use any
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media processing resources including DSP resources.
DSP Usage in Microsoft Skype for Business Survivable Branch Appliance (SBA) and Cloud Connector Edition (CCE) Deployments
DSP resource usage is unaffected within an
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product with an onboard Microsoft Skype for Business SBA or CCE. Sessions that originate from, or terminate to, the onboard SBA or CCE are treated by the
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as exactly equivalent to an off-board SBA or CCE application (analogous to a SIP server residing within its own physically separate processing environment). As such, these calls impose no requirements over and above a call to/from an off-board SIP entity.
DSP Matrix for the IP ↔ IP Operating Mode
The following table provides multiplication factor (to be used with IP ↔ IP session count requirement) to determine DSP resource requirement. The IP↔ IP operating mode is a bidirectional media session, anchored by the
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, between two SIP/RTP endpoints.
An
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can support both IP ↔ IP and TDM ↔ IP modes simultaneously.
To determine the multiplication factor for your transcoding scenario, select from-codec (Codec Type column) and to-codec (Codec Type row) in the following table. The intersecting cell gives you your multiplication factor.
IP ↔ IP DSP Resource Consumption - SBC 1000 IP ↔ IP DSP Multiplication Factor
Note: Densities assume VAD on (60% silence during call), RTCP on, RFC2833 on, and 20ms packet size for all codecs (except 30ms for G.723.1), G.722.2 at 12.65 kbit/s, RTP (unless specified with SRTP).
DSP Resource Consumption for the TDM ↔ IP Operating Mode
The TDM ↔ IP operating mode is a bidirectional media session, anchored by the
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, between non-SIP/RTP endpoint (e.g., an FXS client, an FXO trunk, a PRI/BRI channel, etc.) and a SIP/RTP endpoint.
Resource requirements for TDM/FXx ↔ IP flows can be derived from Table 1. However, the DSP resource requirement presented from Table 1 will be subject to a 50% reduction in value. Note the TDM/FXx leg of the call can be approximated as a G.711 non-encrypted SIP leg from a media services perspective.
For example, in an TDM/FXx ↔ IP flow where encryption on the IP media flow is required with the selection of the G.729ab codec:
- Follow the first data row in table 1 from the first cell all the way to the end; the last cell represents the intersection of an IP ↔ IP call, with G.711 with no encryption being coded to a G.729ab media flow with encryption;
- Next, multiply the value in the cell (1.31 DSP resources) by 50% to achieve the DSP resource requirement value of 0.66.
Note the preceding calculation scheme assumes VAD on (60% silence during call), RTCP on, RFC2833 on, and 20ms packet size for all codecs (except 30ms for G.723.1), G.722.2 at 12.65 kbit/s, RTP(unless specified with SRTP ), and standard Line Echo Canceller.
An
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can support both IP ↔ IP and TDM↔ IP modes simultaneously.
SBC 1000 Configurations and the DSP Resource-to-DSP SKU Mapping
The SBC 1000 Release 6.1 customer-orderable SKUs are pre-populated with DSP physical resources to support calls that require media services. Depending upon the configuration, the SBC 1000 features one, two, or three DSPs (Digital Signal Processors). The mapping of available DSP resources to available DSPs is presented in the following table:
DSPs-to-DSP-Resource Mapping
Number of DSPs | Available DSP Resources |
---|
1 | 64 |
2 | 128 |
3 | 192 |
For the list of available customer-orderable SKUs and the number of DSPs within a given SKU, please contact your Sonus sales representative, or refer to the Partner Configurator.
Calculating DSP Resource Requirement
Follow these steps to determine the appropriate configuration and the number of DSPs you will need.
- Determine the number of IP ↔ IP sessions you need. Be sure to consider future growth.
- Determine the IP ↔ IP DSP multiplication factor from the appropriate table above.
- Multiply the IP ↔ IP session count with the multiplication factor to get your DSP resource requirement number.
- Repeat steps 1-3 for different IP ↔ IP session scenarios to be used in this unit at a given time.
- Determine the number of TDM ↔ IP ↔ sessions you need.
- For simultaneous TDM and IP usage, add all DSP resources from steps 3 and 5, otherwise pick the larger DSP resource requirement of the two.
- If using multiple low-bit rate codecs, apply 20% uplift to the DSP resource requirement number calculated in step 9.
- Refer to the Number of DSPs to DSP Resource Mapping mapping table to determine how many DSPs will be needed to support your needs.
- Calculating the DSP resource requirement for a simple low density IP ↔ IP deployment
- I need 15 IP ↔ IP sessions.
- I want to transcode from G.711 (SRTP) to G.729ab. My multiplication factor is 1.31; therefore, my IP ↔ IP DSP resource requirement number is 15 * 1.31 = 20 (round up from 19.65). I don't need another low-bit rate codec beyond G.729ab ; as such, no 20% uplift is required.
- I also want 4 FXS ↔ IP sessions, where the media on the IP legs will be encoded as G.729ab and encrypted. From table 1, the multiplication factor is 1.31*50%, or 0.66; therefore, my IP ↔ IP DSP resource requirement number is 2 * 0.66 = 2 (round up from 1.31).
- Simultaneous usage – total DSP resource requirement is 20 + 2 = 22.
- Based on the mapping table, I can select any SBC 1000 customer-orderable SKU (as all SKUs feature at least one DSP, with a minimum available 64 DSP resources) with 4 FXS ports.
Example 2 - Calculating the DSP resource requirement for a medium density IP ↔ IP & TDM - IP deployment
- I need 30 IP ↔ IP sessions and 60 TDM ↔ IP sessions (TDM flows across 2 E1 ISDN Primary Rate Interface links).
- Regarding the IP ↔ IP sessions, I want to transcode from G.711 (SRTP) to/from G.722 (SRTP). My multiplication factor is 1.95, and as such my IP ↔ IP DSP resource requirement number is 30 * 1.95 = 57 (round up from 56.5). Furthermore, no 20% uplift is required as we do not have multiple low bit rate codecs in the expected IP ↔ IP flows.
- Regarding the TDM ↔ IP flows, I also want 60 TDM to/from IP sessions, where the media on the IP legs will be encoded as G.722 and encrypted. From table 1, the multiplication factor is 1.95*50%, or 0.98; therefore, my IP ↔ IP DSP resource requirement number is 60 * 0.98 = 59 (round up from 58.8).
- Simultaneous usage: total DSP resource requirement is 59 + 57 = 116.
- Based on the mapping table, I can select any SBC 1000 customer orderable SKU that features a minimum of 2 DSPs and 2 PRI links
Example 3 - Calculating the DSP resource usage possible in a high capacity IP ↔ IP deployment
- I need to support a maximum number of IP ↔ IP sessions with the following call flows: G.723.1 RTP (i.e. non-encrypted) on one leg of the call that is transcoded to either G.723.1 SRTP (encrypted) or G.711 SRTP on the 2nd leg of the call. I am attempting to determine the maximum number of calls I can support.
- I have purchased an SBC 1000 with 3 DSPs (i.e. 192 DSP resources available across the three DSPs).
- The multiplication factor for the selected codec flow is 2.21 (worst case multiplication factor, if all calls are both to & from G.723.1). Furthermore, a 20% uplift is required as we may have multiple low bit rate codecs (G.723.1 ↔ G. 723.1) in the expected IP ↔ IP flows. As such, the true multiplication factor is 2.64
- The simultaneous maximum number of calls subject to DSP intervention, worst case (G.723.1 RTP ↔ G.723.1 SRTP), that may be supported across the system is 192 DSP resources divided by 2.64 = 72 (rounded down from 72.5).
- The simultaneous maximum number of calls subject to DSP intervention, best case (all calls G.723.1 RTP to/from G.711 SRTP), that may be supported across the system is 192 DSP resources divided by 1.53 = 126 (rounded down from 126.3). The 1.53 multiplication factor was derived from table 1, and includes no uplift for multiple low bit rate codecs.
For clarity, please note an SBC 1000 (Release 6.1 and later hardware) can always support 192 total calls. Points 4 and 5 merely identify the maximum simultaneous quantity of calls that are subject to DSP intervention; additional calls are supported when running in direct media or RTP proxy mode.
Considerations for DSP Mode versus RTP Proxy Mode
In the case of RTP Proxy (media pass-though), media passes through the
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but does not use DSP resources.
- If DSP mode is either required or preferred and a media pass-through route is not possible, the SBC must have an available DSP resource. Otherwise the call will fail.
Considerations for FAX
Considerations for DTMF
There are several alternatives for DTMF calls:
- The signaling group can be associated to transmit in band as voice, RFC 2833/4733, or INFO. There is no fallback function.
- In the case of media pass-through mode the DSP does not process the DTMF.