Introduction
This document describes how to determine vCPU and RAM resources required for an
to process planned SIP-based traffic models.
Info |
For detailed background information on calculating DSP requirements, refer to Concepts, Examples, and Considerations for DSP RequirementsBecause many deployments are limited due to constraints imposed by existing equipment, it is important to understand and configure your system for media manipulation.
Purpose
This document is intended to help partners and customers:
• Identify the number of media sessions requiring manipulation supported by a given vCPU and RAM configuration of an
• Identify the number of vCPU and RAM resources to be provisioned to an
to address a given number of media sessions requiring manipulation
Both goals support a partner/customer's effort to ensure traffic processing expectations are met in an
deployment.
A list of The available
configurations (
the Partner "Partner Configurator
"), which includes a description of embedded features and options, is available
in the Partner Portalbehind the partner portal.Definitions and Terminology
Term | Definition |
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Default Media Manipulation Scenario | A basic IP ↔ IP media manipulation session scenario for the is G.711 (RTP) ↔ G.729ab (SRTP). This is considered as the default media manipulation scenario when calculating vCPU and RAM resource requirements. |
Media Manipulation | The action taken by virtual DSP (Digital Signal Processor) logic within the on a bi-directional media session to accomplish some form of intended media manipulation such as translation of media from one codec to another, encrypting/decrypting media, and in-band tone detection. |
Media Session | A bi-directional flow of audio, video, or other real-time information (such as FAX) between two endpoints that may or may not directly subtend the SBC. |
RAM | Random Access Memory. Refer to Random Access Memory. For planning, RAM requirements are always presented in integer GB multiples (Gigabyte). NEEDS TO BE UPDATED GB or MBs? |
vCPU | Refer to https://www.quora.com/What-is-the-difference-between-a-core-a-virtual-CPU-and-a-thread. For planning, vCPU requirements are always presented in integer vCPU multiples. |
Session Density Map
Concepts and Definitions
A media session that does not flow through the The table below is a guide to the maximum capacity of the following on a
:- Media manipulation mode sessions
- RTP proxy session mode sessions requiring encryption/decryption services
- RTP proxy session mode sessions not requiring encryption/decryption services
- Direct media mode sessions supported with a given vCPU and RAM resource assignment
. These flows are common with endpoints that reside within the same physical premises (such as a single branch office) where there is no need for any manipulation of any aspect of the media flow (such as codecs, headers, and encrypting/decrypting) The implications of such sessions on the The table will be used extensively to identify and plan the required resource configuration for a given deployment of an
to address a partner/customer's expected SIP traffic flow. Anchor |
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SessionDensityMap | SessionDensityMap | Caption |
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0 | Table |
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1 | Session Density Map |
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Number of vCPUs | RAM | Registrations | Total Allowed Calls | Proxy Calls Only | Maximum Default Media Manipulation Mode Sessions | Maximum RTP Proxy Mode Sessions |
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1 | 1 GB | 1,000 | 100 | 100 | 50:50 | | 2 | 2 GB | 5,000 | 1,000 | 1,000 | 100:900 | | 4 | 4 GB | 5,000 | 1,000 | 1,000 | 300:700 | |
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How to Determine vCPU and RAM Requirements
Follow these steps to determine the number of vCPUs and RAM required for your
deployment.Determine the number of media manipulation mode sessions needed (taking into account future growth): Use the Session Density Map table to determine the required minimum quantity of vCPUs and RAM to address your required capacity, and then record the values.Determine the additional RTP proxy session mode sessions requiring encryption/decryption services for your
deployment (taking into account future growth):Step | Action |
---|
a | Use the Session Density Map table to determine the available RTP proxy session mode session capacity (with encryption/decryption services) available with the quantity of of vCPUs and RAM recorded from Step 1. |
b | Determine if the available RTP proxy session capacity from (a) above is larger than your required capacity of additional RTP proxy session mode sessions requiring encryption/decryption services: If... | Then |
---|
Capacity from (a) is larger | Proceed to step 3, using the quantity of vCPUs and RAM determined from point 1 above. | Capacity from (a) is smaller | Review the Session Density Map table and increase the quantity of vCPUs and RAM until you arrive at a quantity of both that supports an RTP proxy session capacity (with encryption/decryption services) equal to/greater than your required number of sessions. Record these values. |
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Determine the additional RTP proxy session mode sessions not requiring encryption/decryption services for your deployment (taking into account future growth):Step | Action |
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a | From the Session Density Map table identify the total number of media sessions available with the quantity of vCPUs and RAM recorded from point 2(a) or 2(b) above. |
b | Add the number of required media manipulation mode sessions and RTP proxy session mode sessions requiring encryption/decryption services and record the value. |
c | Subtract the value recorded in 3(b) from the value recorded in 3(a). |
d | Determine if the value in (c) above is greater than/equal to the required additional RTP proxy session mode sessions not requiring encryption/decryption services for your deployment.
If... | Then |
---|
The value in (c) above is greater than/equal to | Proceed to step 4, using the quantity of vCPUs and RAM determined from point 3(a) above. | The value in (c) above is less than | Review the Session Density Map table and increase the quantity of vCPUs and RAM and repeat steps 3(a) through 3(c) until you arrive at a quantity of both that supports an overall session capacity greater than your total required number of sessions across all modes. Record these vCPU and RAM values. |
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are:
- The does not consume any RAM or vCPU resources processing the direct media mode sessions.
- Partners/customers do not need to consider direct media mode sessions when determining an appropriate vCPU and RAM assignment to a given .
Licensing
The
supports a single media session on a 1:1 basis with an associated SIP signaling session. Note the following:• The
requires a license to enable a given quantity of SIP signaling sessions.• The supports a single media session on a 1:1 basis with an associated SIP signaling session without further licensing. Specifically:• A direct media mode session will be supported without any additional licensing licensing beyond the corresponding SIP session license.
• Multiple direct media mode session streams (audio, video, and so on) may be associated with a given SIP session, and will not require additional licensing unless identified elsewhere.
• Only one mode of media is supported against a given SIP session. For example, you cannot have one stream of media in direct media mode, one stream of media in RTP proxy media mode, and both associated with the same SIP signaling session.
Refer to Obtaining and Installing a SWe Lite License for a description of available session and feature licenses.
A media session that flows through the
but does not require media manipulation. These flows may be common with endpoints that may not reside within the same physical premises, but do reside within the same enterprise. If these sessions require access to a public SIP trunk (call flows out of the corporate WAN), there may be a need for encryption/decryption and IP address manipulation services, as many public carriers do not support the forwarding of encrypted media or private IP addresses. However, complex media manipulation such as transcoding will not be required due to enterprise-wide policies surrounding codec usage being in force. The implications of such sessions on the are:1. The
consumes RAM and vCPU resources processing the RTP proxy media mode sessions2. Consumption of RAM and vCPU resources is less than the consumption of RAM and vCPU resources associated with media manipulation mode sessions3. Partners/customers need to consider RTP proxy media mode sessions when determining an appropriate vCPU and RAM assignment to a given The
supports a single RTP proxy media mode session on a 1:1 basis with an associated SIP interworking session. Note the following regarding RTP proxy media mode session:• An RTP proxy media mode session will be supported without any additional licensing beyond the corresponding SIP session license if encryption/decryption services are not required. Services the SBC is capable of applying to such media streams include:
• The modification of IP address and other data within the S/RTP, UDP, IP and other header data as provisioned by the user
• The pass-through of encrypted media traffic (SRTP ↔ SRTP) where no change is required to the previously applied encryption
• An RTP proxy media mode session requiring encryption/decryption services will require additional licensing beyond the corresponding SIP session license. Encryption/decryption services means:
• An RTP proxy media mode session that requires the SBC support RTP ↔ SRTP conversions
• An RTP proxy media mode session that requires SRTP ↔ SRTP changes, such as a cipher change, and authentication algorithm change as the media flow transits the SBC
Other considerations:
• Multiple RTP proxy media mode session streams (audio, video, and so on) may be associated with a given SIP session, and will not require additional licensing unless identified elsewhere
• Only ONE mode of media is supported against a given SIP session; for example, you cannot have one stream of media in direct media mode, one stream of media in RTP proxy media mode, both associated with the same SIP signaling session
Refer to Obtaining and Installing a SWe Lite License for a description of available
session and feature licenses, including instructions on how to enable RTP proxy encryption/decryption services. A media session requires media manipulation is considered a media manipulation mode session. Such flows may be common with endpoints that may communicate across enterprise and public boundaries. The common call types that require media manipulation services include the following (not an exhaustive list):
- Sessions that require transcoding, such as G.711 (common codec in enterprises) ↔ G.729ab (common codec in public networks) translation, G.711 A-law ↔ G.711 µ-law, and so on. Please refer to /*embed link here* for the list of supported codecs by the .
- Transrating, that is, call legs that carry a different time sample size of media, where the performs the translation. Used often when enterprises or the service provider is looking to save bandwidth by reducing packet count at the expense of voice quality (should a packet be dropped).
- Silence suppression, where the looks to remove/insert RTP packets carrying no meaningful media, again to save packet traffic;
- Fax calls.
- Fax tone detection and interworking to T.38 (T.38 support will be available in a future release of the )
- G.711 fax media pass-through, as DSP intervention reduces the likelihood of in-band fax signaling/media issues
- Any call flow where in-band ↔ out-of-band interworking is required. Examples:
- In-band DTMF tone detection interworking with out-of-band RFC 4733 (supersedes RFC 2833)
- In-band DTMF tone detection interworking with SIP INFO messages
- Interworking RTP dynamic payload types, required when the subtended SBC peers use differing payload type identifiers from the dynamic RTP payload range (for example 96 - 127) to identify a common payload format (in other words, codec)
- Any form of media that originates from the SBC in support of call developments. For example:
- Announcement playback
- Local ring back tone
- Music on Hold
- Comfort noise
- Jitter compensation, to maximize user experience with voice quality.
- Certified Skype for Business Phones and Devices interworking with non-certified endpoints. With DSP intervention, s can address media incompatibility issues that at first glance may not be apparent between certified Skype for Business Server endpoints (as documented at https://technet.microsoft.com/en-us/office/dn947482) and other SIP-based client endpoints, such as RTCP reporting interval mismatch, and unrecognized in-band supplementary service requests.
The implications of media manipulation mode
Prepare to configure your with the required number of vCPUs and RAM by referring to Configuring the SBC Edge and SBC SWe Lite.
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title | Concepts and Examples: Click here to expand... |
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Concepts
A media session that does not flow through the
. These flows are common with endpoints that reside within the same physical premises (such as a single branch office) where there is no need for any manipulation of any aspect of the media flow (such as codecs, headers, and encrypting/decrypting) The implications of such sessions on the are:- The does not consume any RAM or vCPU resources processing the direct media mode sessions.
- Partners/customers do not need to consider direct media mode sessions when determining an appropriate vCPU and RAM assignment to a given .
Licensing
The
supports a single media session on a 1:1 basis with an associated SIP signaling session. Note the following:• The
requires a license to enable a given quantity of SIP signaling sessions.• The supports a single media session on a 1:1 basis with an associated SIP signaling session without further licensing. Specifically:• A direct media mode session will be supported without any additional licensing licensing beyond the corresponding SIP session license.
• Multiple direct media mode session streams (audio, video, and so on) may be associated with a given SIP session, and will not require additional licensing unless identified elsewhere.
• Only one mode of media is supported against a given SIP session. For example, you cannot have one stream of media in direct media mode, one stream of media in RTP proxy media mode, and both associated with the same SIP signaling session.
Refer to Obtaining and Installing a SWe Lite License for a description of available
session and feature licenses.A media session that flows through the but does not require media manipulation. These flows may be common with endpoints that may not reside within the same physical premises, but do reside within the same enterprise. If these sessions require access to a public SIP trunk (call flows out of the corporate WAN), there may be a need for encryption/decryption and IP address manipulation services, as many public carriers do not support the forwarding of encrypted media or private IP addresses. However, complex media manipulation such as transcoding will not be required due to enterprise-wide policies surrounding codec usage being in force. The implications of such sessions on the
are are:
1. The consumes - consumes RAM and vCPU resources processing
the RTP proxy - media manipulation mode sessions
2. - Consumption of RAM and vCPU resources is
less - higher than the consumption of RAM and vCPU resources associated with RTP proxy media
manipulation 3. Partners- Partners/customers need to consider
RTP proxy sessions - session density when determining an appropriate vCPU and RAM assignment to a given
RTP Proxy The
supports supports a single
RTP proxy media manipulation mode session on a 1:1 basis with an associated SIP
interworking signaling session. Note the following regarding
RTP proxy media mode sessionlicensing implications:
•
An RTP proxy A media manipulation mode session
will be supported without any requires additional licensing beyond the corresponding SIP session license
if encryption/decryption services are not required. Services the SBC is capable of applying to such media streams include:. Refer to the section above for an example of services available with a media manipulation mode-related license.
• A media manipulation mode session supports encryption/decryption services
• The modification of IP address and other data within the S/RTP, UDP, IP and other header data as provisioned by the user
• The pass-through of encrypted media traffic (SRTP ↔ SRTP) where no change is required to the previously applied encryption
• An RTP proxy media mode session requiring encryption/decryption services will require additional licensing beyond the corresponding SIP session license. Encryption/decryption services means:
•
An RTP proxy media An RTP proxy media manipulation mode session that requires that the SBC support RTP ↔ SRTP conversions.
•
An RTP An RTP proxy media
mode session manipulation mode session that requires SRTP ↔ SRTP changes, such as a cipher change,
and authentication algorithm change, and so on as the media flow transits the SBC.
Other considerations:
• Multiple
RTP proxy media manipulation mode session streams (
audio, video, and so onsuch as audio) may be associated with a given SIP session, and will not require additional licensing unless identified elsewhere.
•
Only ONE Only one mode of media is supported against a given SIP session
; for . For example, you cannot have one stream of media in
direct media manipulation mode session mode, one stream of media in RTP proxy media mode, both associated with the same SIP signaling session.
Refer to Obtaining and Installing a SWe Lite License for a description of
available available
session session and feature licenses, including instructions on how to enable RTP proxy encryption/decryption services.
A media session requires media manipulation is considered a media manipulation mode session. Such flows may be common with endpoints that may communicate across enterprise and public boundaries. The common call types that require media manipulation services include the following (not an exhaustive list):Considerations for Video Interworking in Non-DSP Mode
To come.
Session Density Map
The table below is a guide to the maximum capacity of the following on a
:- Media manipulation mode sessions
- RTP proxy session mode sessions requiring encryption/decryption services
- RTP proxy session mode sessions not requiring encryption/decryption services
- Direct media mode sessions supported with a given vCPU and RAM resource assignment
- Last three columns (provide names) provide maximum values independent of any other session types. For example, with one vCPU ( WORK ON EXAMPLE)
Sessions that require transcoding, such as G.711 (common codec in enterprises) ↔ G.729ab (common codec in public networks) translation, G.711 A-law ↔ G.711 µ-law, and so on. Please refer to /*embed link here* for the list of supported codecs by the The table will be used extensively to identify and plan the required resource configuration for a given deployment of an
.Transrating, that is, call legs that carry a different time sample size of media, where the performs the translation. Used often when enterprises or the service provider is looking to save bandwidth by reducing packet count at the expense of voice quality (should a packet be dropped).Silence suppression, where the looks to remove/insert RTP packets carrying no meaningful media, again to save packet traffic;Fax calls.Fax tone detection and interworking to T.38 (T.38 support will be available in a future release of the )G.711 fax media pass-through, as DSP intervention reduces the likelihood of in-band fax signaling/media issuesAny call flow where in-band ↔ out-of-band interworking is required. Examples: to address a partner/customer's expected SIP traffic flow.
Anchor |
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| SessionDensityMap |
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| SessionDensityMap |
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Caption |
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0 | Table |
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1 | Session Density Map |
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Number of vCPUs | RAM | Registrations | Total Allowed Calls | Maximum Default Media Manipulation Mode Sessions | RTP Proxy Media Mode Sessions, With Encryption Services | RTP Proxy Media Mode Sessions, Without Encryption Services |
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1 | 1 GB | 1,000 | 100 | 50 | 100 | contents of table should be max numbers only | 1 GB | 1,000 | 100 | 50 | 100 | contents of table should be max numbers only | 1 GB | 1,000 | XXX | XXX | 100 | 2 | 2 GB | 5,000 | 1,000 | 100 | 1,000 | | 4 | 2 GB | 0 | 1,000 | 300 | 1,000 | | 4 | 4 GB | 5,000 | 1,000 | 300 | 1,000 | |
VALUES TO BE UPDATED (document the various multipliers for media manip modes.. one for default session (1), then one for 7-11 to 7-11 , then one for every other type of flow (Umar to supply updates). ) calculator to come - Engineering to provide, not release dependent
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How to Determine vCPU and RAM Requirements
Follow these steps to determine the number of vCPUs and RAM required for your deployment.
- Determine the number of media manipulation mode sessions needed (taking into account future growth): From Table 3, identify the required minimum quantity of vCPUs and RAM to address your required capacity, and then record the values.
Determine the additional RTP proxy session mode sessions requiring encryption/decryption services for your deployment (taking into account future growth):
Step | Action |
---|
a | From Table 3, identify the available RTP proxy session mode session capacity (with encryption/decryption services) available with the quantity of of vCPUs and RAM recorded from Step 1. |
b | Determine if the available RTP proxy session capacity from (a) above is larger than your required capacity of additional RTP proxy session mode sessions requiring encryption/decryption services: If... | Then |
---|
Capacity from (a) is larger | Proceed to step 3, using the quantity of vCPUs and RAM determined from point 1 above. | Capacity from (a) is smaller | Review Table 3 and increase the quantity of vCPUs and RAM until you arrive at a quantity of both that supports an RTP proxy session capacity (with encryption/decryption services) equal to/greater than your required number of sessions. Record these values. |
|
Determine the additional RTP proxy session mode sessions not requiring encryption/decryption services for your
deployment (taking into account future growth):
Step | Action |
---|
a | From Table 3, identify the total number of media sessions available with the quantity of vCPUs and RAM recorded from point 2(a) or 2(b) above. |
b | Add the number of required media manipulation mode sessions and RTP proxy session mode sessions requiring encryption/decryption services and record the value. |
c | Subtract the value recorded in 3(b) from the value recorded in 3(a). |
d | Determine if the value in (c) above is greater than/equal to the required additional RTP proxy session mode sessions not requiring encryption/decryption services for your deployment.
If... | Then |
---|
The value in (c) above is greater than/equal to | Proceed to step 4, using the quantity of vCPUs and RAM determined from point 3(a) above. | The value in (c) above is less than | Review Table 3 and increase the quantity of vCPUs and RAM and repeat steps 3(a) through 3(c) until you arrive at a quantity of both that supports an overall session capacity greater than your total required number of sessions across all modes. Record these vCPU and RAM values. |
|
- Prepare to configure your with the required number of vCPUs and RAM by referring to Configuring the SBC Edge and SBC SWe Lite.
In-band DTMF tone detection interworking with out-of-band RFC 4733 (supersedes RFC 2833)In-band DTMF tone detection interworking with SIP INFO messagesInterworking RTP dynamic payload types, required when the subtended SBC peers use differing payload type identifiers from the dynamic RTP payload range (for example 96 - 127) to identify a common payload format (in other words, codec)Any form of media that originates from the SBC in support of call developments. For example:Announcement playbackLocal ring back toneMusic on HoldComfort noiseJitter compensation, to maximize user experience with voice quality.Certified Skype for Business Phones and Devices interworking with non-certified endpoints. With DSP intervention, s can address media incompatibility issues that at first glance may not be apparent between certified Skype for Business Server endpoints (as documented at https://technet.microsoft.com/en-us/office/dn947482) and other SIP-based client endpoints, such as RTCP reporting interval mismatch, and unrecognized in-band supplementary service requests.The implications of media manipulation mode sessions on the
are:- The consumes RAM and vCPU resources processing media manipulation mode sessions
- Consumption of RAM and vCPU resources is higher than the consumption of RAM and vCPU resources associated with RTP proxy media mode sessions
- Partners/customers need to consider media manipulation mode session density when determining an appropriate vCPU and RAM assignment to a given
The
supports a single media manipulation mode session on a 1:1 basis with an associated SIP signaling session. Note the following regarding licensing implications:• A media manipulation mode session requires additional licensing beyond the corresponding SIP session license. Refer to the section above for an example of services available with a media manipulation mode-related license.
• A media manipulation mode session supports encryption/decryption services. Encryption/decryption services means:
• An RTP proxy media manipulation mode session that requires that the SBC support RTP ↔ SRTP conversions.
• An RTP proxy media manipulation mode session that requires SRTP ↔ SRTP changes, such as a cipher change, authentication algorithm change, and so on as the media flow transits the SBC.
Other considerations:
• Multiple media manipulation mode session streams (such as audio) may be associated with a given SIP session, and will not require additional licensing unless identified elsewhere.• Only one mode of media is supported against a given SIP session. For example, you cannot have one stream of media in media manipulation mode session mode, one stream of media in RTP proxy media mode, both associated with the same SIP signaling session.Refer to Obtaining and Installing a SWe Lite License for a description of available session and feature licenses, including instructions on how to enable RTP proxy encryption/decryption services.
Examples
Calculating the DSP Resource Requirements for a Low-Density
Deployment Deployment
1. I need 15 media manipulation mode sessions (sessions will be equivalent to the Default Media Manipulation Scenario defined above). From
the Session Density Map table Table 3 I see a single vCPU and 1 GB of RAM will support this capacity. I record these values as the potential number of vCPU and RAM resources to assign to
my my
. 2. I need 35 additional RTP proxy session mode sessions requiring encryption/decryption services. From the Session Density Map table Table 3 I see a single vCPU and 1 GB of RAM will support up to 50 RTP proxy session mode sessions requiring encryption/decryption services alongside a maximum of 50 media manipulation mode sessions. I continue to use the number of vCPU and RAM resources from point 1 to assign to
my my
. 3. I need 50 additional RTP proxy session mode sessions not requiring encryption/decryption services.(a) From
the Session Density Map table I Table 3, I see a single vCPU and 1 GB of RAM will support up to 100 total sessions.
(b) The sum from adding the required media manipulation mode sessions plus RTP proxy session mode sessions requiring encryption/decryption services is 50.
(c) The difference from subtracting 3(b) from 3( a) results in 50 sessions.
(d) As 3(c) is equal to the 50 RTP proxy session mode sessions not requiring encryption/decryption services, I continue to use the number of vCPU and RAM resources determined from point 2 above to assign to
my my
.NEED ANOTHER EXAMPLE WITH COMPLEX CODEC
Calculating the DSP Resource Requirements for a High-Density
Deployment Deployment
1. I need 100 media manipulation mode sessions (sessions will be equivalent to the Default Media Manipulation Scenario defined above). From
the Session Density Map table I Table 3, I see two vCPU and 2 GB of RAM will support this capacity. I record these values as the potential number of vCPU and RAM resources to assign to
my my
2. I need 400 additional RTP proxy session mode sessions requiring encryption/decryption services. From
the Session Density Map table I Table 3, I see a two vCPU and 2 GB of RAM will support up to 700 RTP proxy session mode sessions requiring encryption/decryption services alongside a maximum of 100 media manipulation mode sessions. I continue to use the number of vCPU and RAM resources from point 1 to assign to
my my
.3. I need 500 additional RTP proxy session mode sessions not requiring encryption/decryption services.
(a) From
the Session Density Map table I see Table 3, I see a two vCPU and 2 GB of RAM will support up to 1000 total sessions.
(b) The sum of adding the required media manipulation mode sessions and RTP proxy session mode sessions requiring encryption/decryption services is 500.
(c) The difference from subtracting 3( b) from 3(a) is 500 sessions.
(d) As 3(c) is equal to the 500 RTP proxy session mode sessions not requiring encryption/decryption services, I continue to use the number of vCPU and RAM resources determined from point 2 above to assign to
my my
.SIP Signaling Group Considerations
SIP Signaling groups (provisioning constructs that represent a connection between the
and and another SIP based peer) can be configured to use either media manipulation session mode or a RTP proxy session mode. Note the following:
• Preference can be set so that either media manipulation session mode or RTP proxy session mode is preferred, but not required.
• If RTP proxy session mode is configured as preferred by both signaling groups, the call proceeds using RTP proxy session mode.
• If media manipulation session mode is configured as preferred by both signaling groups, the call proceeds in media manipulation session mode.
• If one signaling group is configured as media manipulation session mode preferred, and the other signaling group is configured as RTP proxy session mode preferred, the selection of mode is based on the preference of the signaling group associated with the party initiating the call. If media manipulation session mode is preferred but there is no available resource for the initiating party, the initiating party will fall back to attempt the call using RTP proxy session mode.
• After a media path is established between the SIP client and the
in in either media manipulation session mode or RTP proxy session mode, there is no support for a mid-call dynamic switch to change mode – this includes the case of call transfer and conference. This is not necessarily a limitation – it simply emphasizes the importance of understanding the network deployment/architecture. It simply means that the network deployment/architecture needs to be understood.
• If media manipulation session mode is preferred but not required, and if the other signaling group is configured for RTP proxy session mode only, the call goes through using RTP proxy session mode. This improves preservation of the media manipulation session mode resource for calls which require the resources most. However, keep in mind that there is no support for a mid-call dynamic switch to change mode, including the case of call transfer and conference. This is not necessarily a limitation. This also emphasizes the importance of understanding the network deployment/architecture.
• If media manipulation session mode is either required or preferred and a RTP proxy session mode route is not possible,
the the
must have an available media manipulation session mode resource – otherwise, the call will fail.Considerations for DTMF
There are several alternatives for DTMF calls:
• When a DTMF call is received, the
terminates terminates the call and transmits G.711. Other codec types may also be used. However, types such as G.723.1 may be less reliable.
• When a DTMF call is received, the
terminates terminates the call and transmits the signals as out-of-band RFC 2833/4733 compliant messages or out-of-band SIP INFO messages.
• A signaling group can be provisioned to transmit in-band signals as voice, RFC 2833/4733, or SIP INFO messages. There is no fall-back function.
• In the case of RTP proxy session mode, the
does does not process the DTMF.